Distribution of neuropeptides in the limbic system of the rat: The amygdaloid complex

The distribution of six neuropeptides (vasoactive intestinal polypeptide, cholecystokinin octapeptide, substance P, neurotensin, methionine-enkephalin and somatostatin) has been mapped in the amygdala using immunocytochemical methods. Cell bodies containing each peptide showed a differential distribution throughout the various subnuclei. Large numbers of vasoactive intestinal polypeptide and cholecystokinin-octapeptide-containing cell bodies were located in the lateral and cortical nuclei respectively, neurotensin- and methionine enkephalin-containing cell bodies in the central nucleus, and substance P-containing cell bodies primarily in the medial nucleus. Somatostatin-containing cell bodies were found in all nuclei. Neuropeptide-containing fibres were also differentially distributed. Substance P and cholecystokinin fibres formed dense plexuses in the medial nucleus whilst the greatest concentration of vasoactive intestinal polypeptide, neurotensin and methionine enkephalin fibres were seen in the central nucleus. Close observation of serial sections showed that all the neuropeptides studied had extensive intra-amygdaloid pathways and connections with other brain areas.The central nucleus and stria terminalis have particular importance in the organisation of peptides within the amygdala. The central nucleus acts as a focus for a number of converging/diverging peptide pathways and incoming catecholaminergic afferents. The stria terminalis contains all six peptides and represents the major efferent peptidergic system. The amygdala is thought to control a number of endocrine reponses and to regulate complex behavioural functions. The abundance of neuropeptides within the amygdala and their complex pattern of pathways imply that they may act to regulate endocrine responses to external events (e.g. stress) or alter emotional tone, functions thought to be controlled by the amygdala.     

Distribution of neuropeptides in the limbic system of the rat: the bed nucleus of the stria terminalis, septum and preoptic area

The distribution of the neuropeptides vasoactive intestinal polypeptide, cholecystokinin octapeptide, substance P, neurotensin, methionine-enkephalin and somatostatin has been mapped immunocytochemically in the bed nucleus of the stria terminalis, one of the major sites of termination for efferent projections from the amygdala. Immunoreactive fibres and terminals were distributed more or less topographically and largely in accordance with the previously described localization of peptide-containing cell bodies in the amygdala and the amygdaloid projection fields in the bed nucleus as described by neuroanatomical techniques. Thus, vasoactive intestinal polypeptide, which was found in some of the lateral amygdaloid nuclei, had a substantial projection to the lateral bed nucleus. The lateral bed nucleus also contained cholecystokinin-octapeptide, substance P, neurotensin and methionine-enkephalin immunoreactivity which probably derived from the central amygdaloid nucleus, whilst cholecystokinin-octapeptide, and especially substance P-containing fibres, were found in the medial bed nucleus and probably arise from cells in the medial amygdala. Reciprocal amygdalopetal projections were suggested by the presence of substance P- and somatostatin-containing cell bodies in the mediodorsal bed nucleus and vasoactive intestinal polypeptide cells in the lateral bed nucleus, but somatostatin otherwise had a widespread distribution. Numerous local peptidergic connections were also noted both within the bed nucleus and between it and adjacent structures, especially the preoptic area, hypothalamus and the basal ganglia. These data provide further evidence that neuropeptides play a major role in the connectivity of the limbic system and show that the bed nucleus of the stria terminalis is an important relay station, particularly between amygdaloid efferents and other forebrain areas.     

Synaptology and sources of vasoactive intestinal polypeptide and substance p containing axons of the cat celiac ganglion. An experimental electron microscopic immunohistochemical study

We have examined the possible origin of vasoactive intestinal polypeptide (VIP) and substance P-containing axons and the synapses formed by these axons in the celiac ganglion of the cat, by means of ultrastructural immunohistochemistry combined with various surgical lesions.Axons containing VIP as well as those immunopositive for substance P, formed axo-dendritic and axosomatic synapses with principal ganglion cells. After transaction of the superior mesenteric nerve numerous degenerated axonal profiles could be found in the celiac ganglion. Some of these contained VIP immunoreactivity. By contrast in alternate sections stained with substance P antibody only intact axons were labelled.Bilateral vagotomy resulted in the appearance of degenerating axonal profiles in the celiac ganglion, some of which could be stained with substance P antiserum but not with VIP antiserum. Following removal of dorsal root ganglia (Th₆-Th₁₂) from both sides, a large number of degenerated axons were found, many of which were immunopositive for substance P but not for VIP.We conclude that the peripheral input to the celiac ganglion contains VIP fibers which form synapses with principal ganglion cells. Substance P-containing fibers reach the celiac ganglion via the vagal nerve as well as from the dorsal root ganglia, and they form synapses with the principal ganglion cells. It is proposed that the VIP and the substance P-containing axons are involved in two different peripheral reflex loops.     

Distribution of vasoactive intestinal polypeptide in the rat and mouse brain.

The distribution of cell bodies and nerve fibers that combine with antisera to vasoactive intestinal polypeptide (VIP) was studied by immunohistochemistry in combination with radioimmunoassay in the brain of rat and mouse. The highest concentrations (60pmol/g wet wt) of immuno-reactive VIP were found in the cerebral cortex and in certain limbic structures, whereas the concentrations in the basal ganglia, thalamus, lower brain stem, cerebellum and spinal cord were low (<15pmol/g). VIP-immunoreactive cell bodies were found mainly in the cerebral cortex and the limbic system, with the great majority of them in neo- and allocortical areas. In the neocortex the VIP-containing cell bodies were found in layers II-V in all areas. The cells were fusiform or stellate shaped, resembling intracortical and corticocortical association neurones. In the pyriform and entorhinal cortex the cell bodies were located mainly in layer II. In the hippocampal complex VIP-containing cell bodies occurred in both the subiculum, areas CA1 and CA3 and the dentate gyrus. Most of the cells had the appearance of interneurones, some of them probably being identical with basket cells. Of subcortical areas, the amygdala had the largest number of VIP-containing cell bodies; they were numerous in all amygdaloid nuclei except in the central nucleus. Non-cortical areas where there were cell bodies containing VIP included the anterior olfactory nuclei, the bed nucleus of stria terminalis, lateral septum, suprachiasmatic nucleus, superior colliculus, and the mesencephalic periaqueductal gray.VIP-immunoreactive fibres had a distribution which on the whole paralleled that of the cell bodies, suggesting that many of the VIP-containing cells project locally. VIP-containing fibres were numerous in the following areas: the entire neocortex, the pyrifom cortex, the entorhinal cortex, the hippocampal complex, the amygdala (the central nucleus in particular), the anterior olfactory nuclei, the nucleus accumbens, ventral pallidum, bed nucleus of stria terminalis, suprachiasmatic nucleus, medial preoptic nucleus, median eminence, lateral geniculate body, pretectum, superior colliculus, periaqueductal gray, and the lateral parabrachial nucleus. Only few, scattered fibres were seen in other parts of the brain stem, in the striatum, thalamus and spinal cord. The cerebellum was devoid of VIP-containing fibres. VIP-containing neurones seem to form predominantly local projections. In addition, some VIP-containing neurones probably also form long projections, such as descending and transcallosal projections from the cortical cells, and projections from the amygdala to preoptic, hypothalamic and basal forebrain areas.The characteristic telencephalic distribution of the neurones that contain VIP suggests a role for this peptide in cortical and limbic functions.     

P物质、血管活性肠肽和乙酰胆碱能神经在大鼠肠道内的分布及其关系

应用乙酰胆碱酯酶(AChE)组织化学和PAP免疫组织化学方法,比较观察P物质(SP)、血管活性肠肽(VIP)和AChE三种阳性神经元在大鼠十二指肠、空肠、回肠、结肠和直肠内的分布特征及其相互关系。结果显示:SP、VIP、AChE阳性神经神经元和纤维均分布于肠壁各层,从十二指肠、空肠到回肠逐渐增多,但从结肠到直肠则逐渐减少;AChE阳性神经元或纤维在肠壁各层最丰富,其中VIP以粘膜层和粘膜下神经丛较丰富,SP以肠肌丛较丰富;三者的分布密度为AChE>VIP>SP。AChE、SP和VIP阳性神经元胞体及神经纤维在不同肠段的分布密度有明显差异(P<0.05),提示可能与不同肠段肠动力调节功能有关。     

Vasoactive intestinal polypeptide-immunoreactive neurons in rat visual cortex

An antibody to vasoactive intestinal polypeptide (VIP) was used to examine the forms of VIP-positive neurons and the synapses made by VIP-positive axon terminals. Vasoactive intestinal polypeptide-positive cells are most common in layers II and III and the majority of them are typical bipolar neurons, with two primary dendrites which emanate from the upper and lower poles of the cell body. Their somata, which have only a few symmetric and asymmetric synapses, generally have a fusiform or "tear-drop" shape and contain nuclei with a vertically oriented cleft. The dendritic trees are arranged vertically and often extend through five cortical layers. The axons are thin and extend either from the soma or from one of the primary dendrites. The axons also follow a vertical trajectory. Other VIP-positive neurons are modified bipolar cells and a few of them are multipolar cells. The synapses formed by the VIP-positive axon terminals in the neuropil are symmetric in form, and although the synaptic clefts are narrow, the junctions are usually long and continuous, rather like those described for asymmetric synapses. Most of the VIP-positive axon terminals synpase with small dendritic shafts, but a few synapse with neuronal cell bodies. Since the majority of the VIP-positive neurons are bipolar cells it is concluded that these are the source of most of the VIP-positive axon terminals. If this is so, then the VIP-positive bipolar cells form symmetric synapses. This is in contrast to the observations of Peters and Kimerer (1981. J. Neurocytol. 10, 921-946) for the bipolar cells they examined in a Golgi-electron microscopic study had axon terminals forming asymmetric synapses. It is suggested that this disparity can be reconciled if it is assumed that the bipolar cell population consists of subgroups which have different biochemical characteristics and different synaptic relationships.     

Distribution of enteric nerve cell bodies and axons showing immunoreactivity for vasoactive intestinal polypeptide in the guinea-pig intestine

Immunoreactivity for vasoactive intestinal polypeptide has been localized in neurons in the guinea-pig ileum, colon and stomach. In the ileum, 2.5% of the nerve cell bodies of the myenteric plexus and 45% of those of the submucous plexus showed vasoactive intestinal polypeptide-like immunoreactivity. Varicose axons containing vasoactive intestinal polypeptide ramified amongst the nerve cell bodies of both plexuses and in some cases formed rings of varicosities around non-reactive nerve cells. Axons were traced from the myenteric plexus to the circular muscle and deep muscular plexus. There were numerous positive axons running in fine strands within the circular muscle, parallel to the muscle bundles. Axons containing vasoactive intestinal polypeptide were associated with mucosal blood vessels, but few supplied the vascular network of the submucosa; some immunoreactive axons also contributed to the periglandular plexus of the mucosa. There were no changes in the distribution of axons in the ileum after extrinsic denervation.The results are discussed in relation to the possible functional roles of neurons that contain vasoactive intestinal polypeptide in the intestine: the distribution of such nerve cells in the myenteric plexus and of axons in the circular muscle and sphincters is consistent with this polypeptide being a transmitter of enteric inhibitory neurons; it is also possible that vasoactive intestinal polypeptide is the enteric vasodilator transmitter.     

Effect of peripheral nerve section and nerve crush on spinal cord neuropeptides in the rat; increased VIP and PHI in the dorsal horn

An increase in vasoactive intestinal polypeptide (VIP) immunoreactivity in the dorsal lumbar hemisegment L4 of the spinal cord was observed by both radioimmunoassay and immunocytochemistry following sciatic nerve section or crush. Compared to the contralateral control hemisegment there was 125% and 35% more VIP immunoreactivity in the L4 hemisegment ipsilateral to the lesion 14 days following nerve section and crush respectively. The contralateral control hemisegment contained levels similar to L4 hemisegments from unoperated control rats. This increase appeared by immunocytochemistry to be confined to the substantia gelatinosa, in the region of termination of the majority of unmyelinated sciatic nerve afferents. Similar increases to VIP were observed for the peptide PHI, which is closely related to VIP. However, spinal cord substance P and somatostatin immunoreactivities were reduced following nerve section and unchanged following nerve crush whilst neurotensin and bombesin immunoreactivities were not affected following either lesion.Previous studies have shown that peripheral nerve injury produces a number of electrophysiological and biochemical changes in the dorsal horn of the spinal cord, including depletion of substance P in primary afferent neurones.The location of the cell bodies of fibres showing increased immunoreactivity remains to be established. Further studies are required to elucidate how these peptide changes are related to the adaptive processes which occur centrally following peripheral nerve injury.     

Effects of neuropeptides on rat cortical neurons: laminar distribution and interaction with the effect of acetylcholine

The effects of the microiontophoretic application of five different peptides (cholecystokinin octapeptide sulfated form, cholecystokinin octapeptide non-sulfated form, vasoactive intestinal polypeptide, angiotensin-II and substance P) on cortical neurons were studied in rats anaesthetized with urethane. Vertical electrode penetrations were made in the first somatic sensory cortex and the laminar position of the neurons determined by the reconstruction of the tracks based on extracellular dye deposits. The first type of effect observed was an excitation of some cortical neurons. These neurons were mostly found in infragranular layers, specially in layer Vb. Pyramidal tract neurons were more often excited by peptides than the cortical population taken as a whole. Substance P excited the largest percentage of neurons, followed by vasoactive intestinal polypeptide and cholecystokinin octapeptide sulfated form, whereas angiotensin II and cholecystokinin octapeptide non-sulfated form were the least potent in terms of frequency of neurons excited as well as of amplitude of the responses. The vast majority of the neurons excited by a peptide could also be excited by acetylcholine. A second and independent effect of peptides was observed: the neuronal excitation induced by acetylcholine could be depressed by the simultaneous application of peptide. This depressing effect was also the most frequently observed with substance P, followed by cholecystokinin and vasoactive intestinal polypeptide.     

Coexistence of peptide immunoreactivity in sensory neurons of the cat

The coexistence of the neuropeptides substance P, cholecystokinin, somatostatin and vasoactive intestinal polypeptide in cat sensory neurons has been examined using peroxidase-anti-peroxidase immunocytochemistry. Attempts were also made to locate cells containing bombesin, neurotensin, [Met]enkephalin and [Leu]enkephalin but no immunoreactivity was found when antisera to these peptides was used. Cells in the dorsal root ganglia were studied by cutting 5 microns serial wax sections or 15 microns cryostat sections. Coexistence was established by applying the antiserum to each peptide to serially adjacent 5 microns sections and establishing the presence of peptide-like immunoreactivity in each of 4 different sections through a single cell. Results showed that the distribution and combinations of coexistence of these neuropeptides in the cat is extremely complex; three and sometimes all four antisera showing immunoreactivity with a single cell. About 21% of all ganglion cells contained some immunoreactivity but there were certainly some small cells which did not contain any immunoreactivity. The coexistence of these peptides differed markedly from that previously reported in the rat suggesting that interspecific differences in the neuropeptide content of cells might be much greater than they are for classical neurotransmitters. The results are discussed in relation to the possible role of neuropeptides and the regulation of their production by sensory neurons.     

Neuronal configurations in lateral and basolateral amygdala

The lateral and basolateral nuclei of the rat amygdala have been studied with the rapid Golgi method. Both nuclei have similar cell types, which closely resemble cells in the cerebral cortex. Therefore, we suggest that what is known about cortical circuitry can be used as a guide for studying synaptic circuitry in the lateral and basolateral nuclei.

The most abundant neurons that are impregnated in both nuclei are pyramidal cells. They have conical cell bodies and easily recognizable apical and basilar dendrites. The ones in the center of each nucleus have long axes that roughly parallel the long axis of the nucleus. Towards the periphery, pyramidal cells have apical dendrites that either stick directly across the nucleus or follow along a nuclear border. The peripheral dendrites tend to enclose the nuclei. There is considerable overlap among the dendritic trees and the dendrites of one nucleus extend into the territory of the other. Pyramidal cells have extensive axonal systems. The principal axon of basolateral cells usually projects rostrally but long collaterals leave the nucleus in other directions. The axons of lateral nucleus pyramidal cells are also widely distributed. The major thrust of their axons is caudal and lateral.

Stellate cells are the most common variety of the non-pyramidal cells. They occur in both nuclei and have round cell bodies, 10–15 μm diameter, and spherical dendritic trees that are confined to a limited region of the nucleus. Their axons form dense terminal fields that remain within the vicinity of the parent cell's dendritic tree. Another type of non-pyramidal cell is the cone cell, whose non-spiny, varicose dendrites describe cones. These neurons are found mainly in the apex of the lateral nucleus. The most rare non-pyramidal cells are the extended neurons, which have long, straight dendrites that reach beyond the nucleus into surrounding neuropil. They are mostly in the rostral part of the basolateral nucleus but also occur in the lateral nucleus, near the ventricular border. The axons of cone cells and the extended neurons have been only partially impregnated.

We also have examined stellate cells in the guinea-pig lateral and basolateral nuclei. They have many of the same features as those in the rat brain, except that their dendritic trees and axonal systems are more complicated.

There are two large groups of afferents: one consists of longitudinally running axons and the other of transversely coursing fibers. The axons in both groups are thin, have a rather straight course through the nucleus and have only a few collaterals. We have attempted to relate these groups to the known afferent supply of the nuclei. In addition, axons from neurons in the intercalated cell masses and in the claustrum-dorsal endopiriform area enter at least the periphery of the lateral and basolateral nuclei.

Finally, we propose that the lateral and basolateral nuclei are functionally interrelated and that they link exteroceptive sensory data (‘percepts’) with the output of the basolateral nucleus, which is seen to coordinate forebrain areas that direct motivationally-guided behavior. Furthermore, this linked input-output pattern is communicated to the entorhinal cortex and, hence, to the hippocampus where it is encoded.     

Distribution of enteric neurons showing immunoreactivity for substance P in the guinea-pig ileum

Substance P-like immunoreactivity has been localized in whole mount preparations of the isolated layers of the guinea-pig ileum. Axons containing substance P formed dense networks around the nerve cells and ran in the primary, secondary and tertiary nerve bundles of the myenteric plexus. 3.6% of the nerve cell bodies of the myenteric plexus and 11.3% of the cell bodies in the submucous plexus showed immunoreactivity for substance P. Axons ran in fine nerve bundles parallel to the longitudinal muscle, between this muscle and the myenteric plexus. Axons containing substance P also ran in small nerve trunks parallel to the circular muscle throughout its thickness and in the deep muscular plexus at the base of this muscle coat. In the submucosa, these axons ramified amongst ganglion cells of the plexus and ran in the internodal strands. In addition they formed a perivascular network around submucous arteries and contributed to the paravascular nerves following these arteries. Axons containing substance P formed a delicate plexus in the mucosa. After extrinsic denervation the nerves containing substance P that were associated with submucous arteries, and some in the submucous plexus, disappeared. The nerves in the other areas were not detectably different from normal.Comparison with the distribution of somatostatin, enkephalin and vasoactive intestinal polypeptide indicated the neurons containing substance P constitute a separate population within the enteric nervous system.     

Ultrastructure and synaptic connections of vasoactive intestinal polypeptide-like immunoreactive non-pyramidal neurons and axon terminals in the rat hippocampus

In the hippocampus, antibody raised against vasoactive intestinal polypeptide (VIP) labeled perikarya and processes of non-pyramidal neurons whereas these structures remained unlabeled in pyramidal cells and granule cells. In the present study, VIP-immunostaining was used to investigate the fine structure and synaptic connections of identified non-pyramidal neurons and of imrnunoreactive axon terminals in the CA1 region of the rat hippocampus by means of electron microscopic immunocytochemistry.From a number of cells studied, two VIP-like imrnunoreactive non-pyramidal neurons in the regio superior were selected for an electron microscopic analysis of serial thin sections. These cells were different with regard to the location of their cell bodies and the orientation of their dendrites. One cell was located in the stratum lacunosum-moleculare with dendritic processes oriented parallel to the hippocampal fissure. The second neuron was found in the inner one-third of the stratum radiatum. The dendrites of this cell ran nearly parallel to the ascending apical dendrites of the pyramidal cells. Both cells had a round or ovoid perikaryon and an infolded nucleus. The aspinous dendrites of both neurons were densely covered with synaptic boutons. These terminals were small, filled with spherical vesicles and established asymmetric synaptic contacts. No variations in the fine structure of the presynaptic boutons were found along the course of the labeled dendrites through the various hippocampal layers, although different afferents are known to terminate in these layers.Vasoactive intestinal polypeptide-like immunopositive axon terminals course through all layers of the hippocampus. In the stratum pyramidale they established symmetric synaptic contacts with the perikarya of pyramidal cells. In the stratum radiatum they made symmetric contacts with the shafts of apical dendrites of pyramidal cells but never contacted dendritic spines.The symmetric contacts with pyramidal cell perikarya suggest an involvement of the VIP-like immunoreactive axon terminals in pyramidal cell inhibition.     

Origin of peptide-containing fibers in the inferior mesenteric ganglion of the guinea-pig: Immunohistochemical studies with antisera to substance P,enkephalin, vasoactive intestinal polypeptide,cholecystokinin and bombesin

After different denervation procedures the guinea-pig inferior mesenteric ganglion was analysed by immunohistochemistry using antisera to substance P, enkephalin, vasoactive intestinal polypeptide, cholecystokinin and bombesin. The results demonstrate that each of the nerve trunks connected to the ganglion carries specific peptidergic pathways. Thus, the lumbar splachnic nerves contain substance P-immunoreactive primary afferent neurons, which to a large extent traverse the ganglion, and enkephalin-immunoreactive preganglionic neurons; the colonie nerves carry vasoactive intestinal polypeptide-, cholecystokinin- and bombesin-immunoreactive fibers from the distal colon to the ganglion; the hypogastric nerves contain vasoactive intestinal polypeptide-positive fibers from the pelvic plexus; and the intermesenteric nerve contains vasoactive intestinal polypeptide, cholecystokinin, substance P and enkephalin from divergent sources. By studying accumulations of peptides in ligated lumbar splanchnic, intermesenteric, hypogastric and colonic nerves the existence of these major peptidergic pathways was confirmed and evidence was obtained for additional, not so prominent, peptidergic projections. The results are discussed in view of earlier morphological and physiological studies.     

Immunohistochemical studies of the enteric nervous system in tissue culture and in situ: localization of vascoactive intestinal polypeptide (VIP), substance-P and enkephalin immunoreactive nerves in the guinea-pig gut

Immunofluorescence methods have been used to determine the detailed distribution of vasoactive intestinal polypeptide (VIP), substance-P and enkephalin nerve fibres in fixed cryostat sections from guinea-pig duodenum, jejunum, ileum, caecum at the site of the taenia coli, and proximal and distal colon. A novel method is used involving immunostaining of tissue culture preparations of both myenteric and submucous plexuses. These preparations allow each plexus to be studied in isolation from all axonal input for the first time, since they provide unequivocal extrinsic denervation together with severance of any intrinsic connections between the plexuses. In tissue sections the most prominent sites of VIP and substance-P immunoreactive fibres are the ganglia of the myenteric and submucous plexuses, the circular muscle layer and the longitudinal muscle of the taenia coli. In addition, VIP is prominent in the lamina propria of the submucosa except in the caecum. Enkephalin-immunopositive fibres are restricted to the ganglia of the myenteric plexus, the circular muscle layer and the longitudinal layer of the taenia coli. The culture preparations reveal that intrinsic ‘VIP neurons’ are common in the submucous plexus of the caecum and colon. They are also present, but in much lower numbers, in the myenteric plexus of the small intestine and colon but are not found in the myenteric plexus of the caecum. Intrinsic ‘substance-P neurons’ are present in the myenteric plexus from the small intestine, caecum and colon as well as in the submucous plexus of the colon; intrinsic ‘substance-P neurons’ are not found in the submucous plexus of the caecum. ‘Enkephalin neurons’ are numerous in the myenteric plexus of the small intestine, caecum and colon but are absent from the submucous plexus. Immunoreactivity is compared in the normal and denervated caecum by both the histochemical method and by radioimmunoassay of tissue extracts. In conjunction with the studies on tissue cultures, the results provide evidence for intrinsic reciprocal connections between the myenteric and submucous plexus of the caecum by neurons containing VIP and substance-P.An extensive comparison of these results with data from functional studies shows that the distribution of VIP, substance-P and enkephalin fibres in the gut is broadly in agreement with present knowledge of the action of these peptides on gut tissue, if it is assumed that they function as neurotransmitters or neuromodulators. In some instances, however, peptide-containing fibres and pathways are found which do not correlate with present knowledge obtained from functional studies. These observations provide new clues to the role of peptide neurons in gut function.     

Compartment analysis of vascular effects of neuropeptides an capsaicin in the pig nasal mucosa

The vascular effects of local infusion of capsaicin, substance P (SP), calcitonin generelated peptide (CGRP) and vasoactive intestinal polypeptide (VIP) were monitored in an experimental model on the pig nasal mucosa. Arterial, venous and superficial mucosal blood flow (laser-Doppler flowmetry) as well as mucosal volume, reflecting changes in capacitance vessels were studied in parallel. All substances induced concentration dependent increases in the parameters studied with the exception of the decrease in the superficial mucosal flow induced by vasoactive intestinal polypeptide. This latter finding was interpreted as a stealing phenomenon and suggests that vasoactive intestinal polypeptide mainly exerts its vasodilatory effect in the deeper glandular layers of the nasal mucosa. The vasodilatory effect of capsaicin, except the laser-Doppler signal, was markedly reduced by pretreatment with a combination of the ganglionic blocking agent chlorisondamine and atropine implying that capsaicin evokes a central reflex with a final parasympathetic pathway and release of agents like vasoactive intestinal polypeptide. The remaining capsaicin response may depend on a local effect with axon reflexes and the release of sensory neuropeptides with actions on superficial mucosal blood flow.     

Vasoactive intestinal polypeptide afferents to the bed nucleus of the stria terminalis in the rat: an immunohistochemical and biochemical study

Vasoactive intestinal polypeptide (VIP) has a markedly heterogeneous distribution in the rat bed nucleus of the stria terminalis. The dorsal bed nucleus contains the highest concentration of VIP in the rat brain, with the exception of the suprachiasmatic nucleus, 4-fold higher than the VIP concentration in the frontal cortex. These biochemical findings agree well with the immunohistochemical analysis of this area. The bed nucleus is also a heterogeneous nucleus with respect to the afferent VIP pathways which innervate it. A combination of immunohistochemical and biochemical techniques was used to examine VIP innervation of the bed nucleus after knife cuts designed to interrupt ascending brainstem, stria terminalis and ventral amygdalofugal inputs to the bed nucleus. The results obtained suggest that (1) ascending pathways arising in the mesencephalon at the level of the dorsal raphe nucleus send VIP fibers to the dorsal but not the ventral bed nucleus, (2) afferent VIP fibers which travel to the bed nucleus via the stria terminalis contribute a diffuse VIP innervation to both the dorsal and ventral bed nucleus and (3) a newly described ventral amygdalofugal VIP pathway to the bed nucleus contributes a major input to the dorsal, but not to the ventral bed nucleus. These three pathways probably account for the entire extrinsic VIP input to the bed nucleus. The finding that the bed nucleus is heterogeneous both with respect to VIP content and afferent VIP inputs serves to clarify previous, apparently discrepant, reports that both the stria terminalis and ascending pathways constitute the major VIP input to the bed nucleus of the stria terminalis.