Serotonergic Nerve Fibers Research Articles

Globus pallidus, but not entopeduncular nucleus, 6-OHDA-induced lesion attenuates L-Dopa-induced dyskinesia in the rat model of Parkinson's disease

Although extrastriatal dopaminergic (DAergic) systems are being recognized as contributors to Parkinson's disease (PD) pathophysiology, the role of extrastriatal DA depletion in L-Dopa-induced dyskinesia (LID) is still unknown. In view of the physiologic actions of DA on pallidal neuronal activity and the effects on motor behavior of local injection of DA drugs, the loss of the external (GPe, GP in rodents) and internal (GPi, entopeduncular nucleus (EP) in rodents) pallidal DAergic innervation might differentially contribute to LID. A role of pallidal serotonergic (SER) terminals in LID has been highlighted, however, the effect of DAergic innervation is unknown.We investigated the role of DAergic pallidal depletion on LID. Rats were distributed in groups which were concomitantly lesioned with 6-OHDA or vehicle (sham) in the GP, or EP, and in the medial forebrain bundle (MFB) as follows: a) MFB-sham+GP-sham, b) MFB-sham+GP-lesion, c) MFB-lesion+GP-sham, d) MFB-lesion+GP-lesion, e) MFB-sham+EP-sham, f) MFB-sham+EP-lesion, g) MFB-lesion+EP-sham, and h) MFB-lesion+EP-lesion. Four weeks later, animals were treated with L-Dopa (6 mg/kg) twice daily for 22 days.. Immunohistochemical studies were performed in order to investigate the changes in pallidal SER and serotonin transporter (SERT) levels.GP, but not EP, DAergic denervation attenuated LID in rats with a concomitant MFB lesion (p < 0.01). No differences were found in GP SERT expression between groups of animals developing or not LID.These results provide evidence of the relevance of GP DAergic innervation in LID. The conversion of levodopa to DA in GP serotonergic nerve fibers appears not to be the major mechanism underlying LID.

Pefloxacin induced changes in serotonergic innervation and mast cell number in rat salivary glands

Pefloxacin is a second-generation fluoroquinolone antibiotic. Besides its advantageous characteristics, side effects including the hypofunction of salivary glands, decreased saliva production, and peripheral neuropathy were observed during the administration of pefloxacin. The aim of this study was to investigate the changes in the number of serotonergic immunoreactive fibers and mast cells after pefloxacin treatment in the parotid and sublingual glands of rats to detect the possible neurotoxic effect of pefloxacin. The adult female rats were treated with intraperitoneal (i.p.) injection of pefloxacin for three or seven days (at a concentration of 20 mg/100g body weight) and the serotonergic innervation pattern along with the change in mast cell number were evaluated by using histochemistry and immunohistochemistry in the parotid and sublingual glands. We found that a three-day treatment significantly increased the number of immunoreactive serotonergic nerve fibers, but after a seven-day treatment the number of serotonin positive nerve fibers decreased almost to values of the control group. The alteration of mast cell number was parallel with the changes of the serotonin positive fibers during the treatment. These results suggest that pefloxacin treatment can modify the finely controlled communication between the immune- and the peripheral nervous systems, resulting neurogenic inflammatory process. The background of this process is the altered serotonergic innervation and the increased number of activated mast cells releasing different mediators for example histamine, which can finally lead to reduced number of serotonin positive nerve fibers after a seven-day treatment of pefloxacin leading to atrophy and hypofunction of the salivary glands.

Serotonergic projections to the ventral respiratory column from raphe nuclei in rats

The ventral respiratory column (VRC) generates rhythmical respiration and is divided into four compartments: the Bötzinger complex (BC), pre-Bötzinger complex (PBC), rostral ventral respiratory group (rVRG), and caudal ventral respiratory group (cVRG). Serotonergic nerve fibers are densely distributed in the rostral to caudal VRC and serotonin would be one of the important modulators for the respiratory control in the VRC. In the present study, to elucidate detailed distribution of serotonergic neurons in raphe nuclei projecting to the various rostrocaudal levels of VRC, we performed combination of retrograde tracing technique by cholera toxin B subunit (CTB) with immunohistochemistry for tryptophan hydroxylase 2 (TPH2). The double-immunoreactive neurons with CTB and TPH2 were distributed in the both rostral and caudal raphe nuclei, i.e. dorsal raphe nucleus, raphe magnus nucleus, gigantocellular reticular nucleus alpha and ventral parts, lateral paragigantocellular nucleus, parapyramidal area, raphe obscurus nucleus, and raphe pallidus nucleus. The distributions of double-immunoreactive neurons were similar among injection groups of BC, PBC, anterior rVRG, and posterior rVRG/cVRG. In conclusion, serotonergic neurons in both rostral and caudal raphe nuclei projected throughout the VRC and these serotonergic projections may contribute to respiratory responses to various environmental and vital changes.

Reactive changes in neurons of the raphe serotonergic ом nucleus of after experimental stress in the neonate period and buspirone therapy

The identification of the raphe nucleus neurons reactive changes after experimental stress in the newborn period is necessary for a better understanding of the mechanisms of damage and adaptation of the serotonergic system in the brain during postnatal development. It is well known that the raphe serotonergic nucleus is the largest source of serotonergic nerve fibers through which the connection with the hypothalamus and other projection centers of “positive reinforcement system”. The study of reactive changes raphe nucleus neurons after experimental stress in the newborn period is necessary for a better understanding of the mechanisms of damage and adaptation of the serotonergic system in the brain during postnatal development as well as for possible correction of behavioral disorders. In 37 day old rats after injection of buspirone (experimental animals) and control (injected with physiologists cal solution) studied pain response in the formalin test (2.5 % injection solution of formalin in 1.0 l of a sole of the hind limb). In sections macrocellular raphe nuclei stained by Nissl, counted the number of unmodified, hypochromic, shrunken and hyperchromatic, shadowly cells, established area little changed neurons. Measured as the distance between the bodies of neurons and glial cells between the bodies and the bodies of neurons. It was found that after the simulation of stress in a large raphe nucleus neurons developing degenerative and compensatory-adaptive changes. Reduces the number and size of bodies of neurons containing substance Nissl, wrinkling occurs, strengthening and weakening of staining, the growth of the share of shadowly neurons. Also activated glioneuronal and interneuronal relationships. Reactive changes in the cells exposed to the compensation correction drugs that block receptors for serotonin.

Extensive projections of myenteric serotonergic neurons suggest they comprise the central processing unit in the colon

5-Hydroxytryptamine (5-HT, serotonin) is an important regulator of colonic motility and secretion; yet the role of serotonergic neurons in the colon is controversial. We used immunohistochemical techniques to examine their projections throughout the enteric nervous system and interstitial cells of Cajal (ICC) networks in the murine proximal to mid colon. Serotonergic neurons, which were mainly calbindin positive, occurred only in myenteric ganglia (1 per 3 ganglia). They were larger than nNOS neurons but similar in size to Dogiel Type II (AH) neurons. 5-HT neurons, appeared to make numerous varicose contacts with each other, most nNOS neurons, Dogiel Type II/AH neurons and glial cells. 5-HT, calbindin and nNOS nerve fibers also formed a thin perimuscular nerve plexus that was associated with ganglia, which contained both nNOS positive and negative neurons, which lay directly upon the submucosal pacemaker ICC network. Neurons in perimuscular ganglia were surrounded by 5-HT varicosities. Submucous ganglia contained nNOS positive and negative neurons, and calbindin positive neurons, which also appeared richly supplied by serotonergic nerve varicosities. Serotonergic nerve fibers ran along submucosal arterioles, but not veins. Varicosities of serotonergic nerve fibers were closely associated with pacemaker ICC networks and with intramuscular ICC (ICC-IM). 5-HT2B receptors were found on a subpopulation of non-5-HT containing myenteric neurons and their varicosities, pacemaker ICC-MY and ICC-IM. Myenteric serotonergic neurons, whose axons exhibit considerable divergence, regulate the entire enteric nervous system and are important in coordinating motility with secretion. They are not just interneurons, as regularly assumed, but possibly also motor neurons to ICC and blood vessels, and some may even be sensory neurons.

Serotonergic nerve fibers in l-DOPA-derived dopamine release and dyskinesia

The 5-HT (5-hydroxytryptamine) system has been assigned a key role in the development of 3,4-dihydroxyphenyl-l-alanine (l-DOPA)-induced dyskinesia, mainly due to 5-HT neuronal ability to decarboxylate l-DOPA into dopamine. Nevertheless, knowledge of l-DOPA-induced events that could lead to development of dyskinesias are limited and therefore the present work has evaluated (i) the role of the 5-HT system in l-DOPA-derived dopamine synthesis when dopamine neurons are present, (ii) l-DOPA-induced effects on striatal dopamine release and clearance, and on 5-HT nerve fiber density, and (iii) the behavioral outcome of altered 5-HT transmission in dyskinetic rats. Chronoamperometric recordings demonstrated attenuated striatal l-DOPA-derived dopamine release (∼30%) upon removal of 5-HT nerve fibers in intact animals. Interestingly, four weeks of daily l-DOPA treatment yielded similar-sized dopamine peak amplitudes in intact animals as found after a 5-HT-lesion. Moreover, chronic l-DOPA exposure attenuated striatal 5-HT nerve fiber density in the absence of dopamine nerve terminals. Furthermore, fluoxetine-induced altered 5-HT transmission blocked dyskinetic behavior via action on 5-HT1A receptors. Taken together, the results indicate a central role for the 5-HT system in l-DOPA-derived dopamine synthesis and in dyskinesia, and therefore potential l-DOPA-induced deterioration of 5-HT function might reduce l-DOPA efficacy as well as promote the upcoming of motor side effects.

Sexual differences in serotonin distribution and induction of synchronous larval release by serotonin in the freshwater mussel Hyriopsis bialatus

We have established an in vitro glochidial culture of the freshwater mussel, Hyriopsis (Hyriopsis) bialatus, with the potential of restoring natural populations. However, to develop a successful in vitro culture process the synchronous release of glochidia needs to be achieved. In this study we investigated the distribution of serotonin and its effect on inducing synchronous parturition. Using confocal microscopy on whole-mounted tissues, we show that serotonin is highly expressed in the peripheral neuron somata and their axonal processes in the central neuropils of the visceral ganglion. Serotonergic nerve fibres were also detected along the branchial nerve innervating the demibranchs. A hierarchical ramification from the branchial cord into nerve rootlets and subsequently into the small nerve fibres within the demibranch epithelium was evident throughout this organ. In both visceral ganglia and demibranchs, immunoreactivity of serotonin was relatively higher in female than male tissues, suggesting a role of serotonin in female reproductive functions. Administration of serotonin to the demibranchs, the sites of larval settlement, stimulated synchronous parturition in a dosedependent manner. A single-dose injection of serotonin yielded a large number of released larvae within 1–2 h, with no adverse effect on the quality of cultured larvae.

Dopamine release from serotonergic nerve fibers is reduced in L‐DOPA‐induced dyskinesia

L-DOPA is the most commonly used treatment for symptomatic control in patients with Parkinson's disease. Unfortunately, most patients develop severe side-effects, such as dyskinesia, upon chronic l-DOPA treatment. The patophysiology of dyskinesia is unclear; however, involvement of serotonergic nerve fibers in converting l-DOPA to dopamine has been suggested. Therefore, potassium-evoked dopamine release was studied after local application of l-DOPA in the striata of normal, dopamine- and dopamine/serotonin-lesioned l-DOPA naïve, and dopamine-denervated chronically l-DOPA-treated dyskinetic rats using in vivo chronoamperometry. The results revealed that local l-DOPA administration into normal and intact hemisphere of dopamine-lesioned l-DOPA naïve animals significantly increased the potassium-evoked dopamine release. l-DOPA application also increased the dopamine peak amplitude in the dopamine-depleted l-DOPA naïve striatum, although these dopamine levels were several-folds lower than in the normal striatum, whereas no increased dopamine release was found in the dopamine/serotonin-denervated striatum. In dyskinetic animals, local l-DOPA application did not affect the dopamine release, resulting in significantly attenuated dopamine levels compared with those measured in l-DOPA naïve dopamine-denervated striatum. To conclude, l-DOPA is most likely converted to dopamine in serotonergic nerve fibers in the dopamine-depleted striatum, but the dopamine release is several-fold lower than in normal striatum. Furthermore, l-DOPA loading does not increase the dopamine release in dyskinetic animals as found in l-DOPA naïve animals, despite similar density of serotonergic innervation. Thus, the dopamine overflow produced from the serotonergic nerve fibers appears not to be the major cause of dyskinetic behavior.

Lack of analgesic efficacy of spinal ondansetron on thermal and mechanical hypersensitivity following spinal nerve ligation in the rat

The balance between descending inhibition and facilitation is thought to be disturbed in chronic pain states. Increased facilitation by spinally released serotonin has been suggested by demonstration that mechanically evoked neuronal responses of wide dynamic range neurons are inhibited by 5-HT3 receptor antagonists in rats following spinal nerve ligation (SNL) but not sham operation. Despite these physiologic data, the effects of spinal 5-HT3 receptor blockade on behavioral hypersensitivity and neurochemical alterations in spinal serotonergic system have not been thoroughly investigated following spinal nerve ligation in the rat. To test this, we acutely injected intrathecal ondansetron in rats between 14 and 30 days after SNL and assessed effects on thermal and mechanical hypersensitivity. We also determined the density of serotonergic nerve fibers, serotonin content and the levels of 5-HT3 receptors within the spinal cord at this time point. Intrathecal ondansetron (1, 3, 10, 30, and 100 μg) produced no effect on behavioral measures of thermal or mechanical hypersensitivity whereas intrathecal morphine (1 μg) and gabapentin (200 μg) partially reversed thermal and mechanical hypersensitivity following SNL. In addition, SNL did not alter the density of serotonergic fibers or 5-HT3 receptor immunoreactivity or spinal tissue content of 5-HT within the dorsal horn. These results do not support anatomic plasticity of descending serotonergic pathways or tonic 5-HT3 receptor activity in maintaining hypersensitivity after nerve injury and in contrast to previous studies fail to demonstrate an anti-hypersensitivity effect of intrathecal injection of the 5-HT3 receptor antagonist ondansetron. Importantly, behavioral measures of mechanical hypersensitivity assess threshold responses whereas physiological studies of mechanically evoked neuronal responses involve application of suprathreshold stimuli. Thus, suprathreshold or more intense stimuli may be necessary to recruit descending serotonergic facilitatory drive required to observe the inhibitory effects of ondansetron on spinal neuronal excitability and behavioral hypersensitivity.

Grafts of Schwann cells engineered to express PSA-NCAM promote functional recovery after spinal cord injury

Schwann cells (SCs) are among the most attractive cellular candidates for the development of remyelination therapies for CNS lesions. Yet, their integration in the CNS is inhibited by astrocytes and therefore the use of genetically modified SCs with improved properties is an alternative promising approach. Our strategy for ameliorating the therapeutic potential of SCs has been to alter their adhesive properties by expressing on their surface the polysialylated (PSA) form of the neural cell adhesion molecule NCAM. In the present study, SCs from transgenic GFP-mice were transduced with a retroviral vector encoding sialyl-transferase X (STX), the enzyme responsible for transferring PSA on NCAM. Engineered STX-GFP-SCs with sustained PSA expression were thus generated and were found to have improved ability to associate with astrocytes in vitro. Importantly, when these cells were transplanted in vivo in a mouse model of spinal cord injury they promoted faster and significantly greater functional recovery as compared to using SCs transduced with a control retroviral vector or no cells at all. Morphological analysis indicated that the improved locomotor recovery correlated with earlier and enhanced remyelination by grafted STX-GFP-SCs, increased remyelination by host SCs as well as enhanced differentiation/remyelination by resident oligodendrocyte precursors. Moreover, sprouting of regenerating serotonergic nerve fibres, which are known to be important for locomotion and recovery after injury, was observed into and across the lesion site. These results underline the potential therapeutic benefit of early activation of myelin-forming cells to differentiate and remyelinate severed axons thus restoring functions in CNS trauma and/or demyelinating diseases.

Pharmacology of serotonin-induced salivary secretion in Periplaneta americana

The acinar salivary gland of the cockroach, Periplaneta americana, is innervated by dopaminergic and serotonergic nerve fibers. Stimulation of the glands by serotonin (5-hydroxytryptamine, 5-HT) results in the production of a protein-rich saliva, whereas stimulation by dopamine results in saliva that is protein-free. Thus, dopamine acts selectively on ion-transporting peripheral cells within the acini, and 5-HT acts on protein-producing central cells. We have investigated the pharmacology of the 5-HT-induced secretory activity of isolated salivary glands of P. americana by testing several 5-HT receptor agonists and antagonists. The effects of 5-HT can be mimicked by the non-selective 5-HT receptor agonist 5-methoxytryptamine. All tested agonists that display at least some receptor subtype specificity in mammals, i.e., 5-carboxamidotryptamine, (±)-8-OH-DPAT, (±)-DOI, and AS 19, were ineffective in stimulating salivary secretion. 5-HT-induced secretion can be blocked by the vertebrate 5-HT receptor antagonists methiothepin, cyproheptadine, and mianserin. Our pharmacological data indicate that the pharmacology of arthropod 5-HT receptors is remarkably different from that of their vertebrate counterparts.

A serotonergic system in the brain of the Antarctic fish, Trematomus bernacchii

The immunohistochemical distribution of serotonin-containing nerve fibres and cells has been described in the brain of the Antarctic fish, Trematomus bernacchii. The largest serotonergic system was associated with the diencephalic and rhombencephalic ventricles. In particular, serotonin-positive cells have been found in the lateral recess and neuropile zone of the diencephalic ventricle, where we have identified the serotonergic portion of the paraventricular organ. Numerous serotonin cells were localized in the dorsal nucleus of the raphe, the dorsal tegmental nucleus and the central gray. Two large cell groups, arranged in a pair of well-defined columns and connecting the central gray with the dorsal reticular formation, were immunostained in the region of the trigeminal nuclei. In addition, few positive cells have been found in the preoptic area and the cerebellar valvula, and few serotonergic nerve fibres, probably belonging to the lateral lemniscus, have been identified. The distribution of serotonin elements in the brain of T. bernacchii has been compared with that described in other fish, where it showed some modifications in the immunoreactive pattern. Finally, the lack of a serotonergic system at the level of the reticular superior formation has been reported; however, it was not possible to rule out a phylogenetic or environmental explanation.

The effects of dopamine receptor agonists and antagonists on the secretory rate of cockroach ( Periplaneta americana) salivary glands

The acinar salivary glands of the cockroach, Periplaneta americana, are innervated by dopaminergic and serotonergic nerve fibers. Serotonin stimulates the secretion of protein-rich saliva, whereas dopamine causes the production of protein-free saliva. This suggests that dopamine acts selectively on ion-transporting peripheral cells within the acini and the duct cells, and that serotonin acts on the protein-producing central cells of the acini. We have investigated the pharmacology of the dopamine-induced secretory activity of the salivary gland of Periplaneta americana by testing several dopamine receptor agonists and antagonists. The effects of dopamine can be mimicked by the non-selective dopamine receptor agonist 6,7-ADTN and, less effectively, by the vertebrate D1 receptor-selective agonist chloro-APB. The vertebrate D1 receptor-selective agonist SKF 38393 and vertebrate D2 receptor-selective agonist R(−)-TNPA were ineffective. R(+)-Lisuride induces a secretory response with a slower onset and a lower maximal response compared with dopamine-induced secretion. However, lisuride-stimulated glands continue secreting saliva, even after lisuride-washout. Dopamine-induced secretions can be blocked by the vertebrate dopamine receptor antagonists cis( Z)-flupenthixol, chlorpromazine, and S(+)-butaclamol. Our pharmacological data do not unequivocally indicate whether the dopamine receptors on the Periplaneta salivary glands belong to the D1 or D2 subfamily of dopamine receptors, but we can confirm that the pharmacology of invertebrate dopamine receptors is remarkably different from that of their vertebrate counterparts.

Distribution of serotonergic and dopaminergic nerve fibers in the salivary gland complex of the cockroach Periplaneta americana

BackgroundThe cockroach salivary gland consists of secretory acini with peripheral ion-transporting cells and central protein-producing cells, an extensive duct system, and a pair of reservoirs. Salivation is controled by serotonergic and dopaminergic innervation. Serotonin stimulates the secretion of a protein-rich saliva, dopamine causes the production of a saliva without proteins. These findings suggest a model in which serotonin acts on the central cells and possibly other cell types, and dopamine acts selectively on the ion-transporting cells. To examine this model, we have analyzed the spatial relationship of dopaminergic and serotonergic nerve fibers to the various cell types.ResultsThe acinar tissue is entangled in a meshwork of serotonergic and dopaminergic varicose fibers. Dopaminergic fibers reside only at the surface of the acini next to the peripheral cells. Serotonergic fibers invade the acini and form a dense network between central cells. Salivary duct segments close to the acini are locally associated with dopaminergic and serotonergic fibers, whereas duct segments further downstream have only dopaminergic fibers on their surface and within the epithelium. In addition, the reservoirs have both a dopaminergic and a serotonergic innervation.ConclusionOur results suggest that dopamine is released on the acinar surface, close to peripheral cells, and along the entire duct system. Serotonin is probably released close to peripheral and central cells, and at initial segments of the duct system. Moreover, the presence of serotonergic and dopaminergic fiber terminals on the reservoir indicates that the functions of this structure are also regulated by dopamine and serotonin.

Serotonergic nerve fibers in the primary olfactory pathway of the larval sea lamprey, Petromyzon marinus

Serotonergic nerve fibers in the primary olfactory pathway of the larval sea lamprey, Petromyzon marinus

Serotonergic nerve fibers in the primary olfactory pathway of the larval sea lamprey,Petromyzon marinus

In this study, serotonin (5-hydroxytryptamine; 5HT)-immunoreactive (5HT-IR) neuronal fibers were identified in the primary olfactory pathway of the sea lamprey. These neurons are likely part of a nonolfactory neural system that innervates the olfactory sac. Cell bodies with 5HT immunoreactivity predominated in the lamina propria of the rostral portion of the nasal cavity and were less prevalent adjacent to the olfactory epithelium. The 5HT-IR fibers were parallel to axons of the olfactory receptor neurons in the lamina propria of the olfactory mucosa and in the olfactory nerve. Serotonergic fibers crossed from the olfactory nerve into the olfactory bulb or branched in the caudal portion of the olfactory nerve and terminated at the junction of the olfactory nerve with the olfactory bulb. In the dorsal olfactory bulb, 5HT-IR fibers coursed along the layer of olfactory fibers. Throughout the layer with glomeruli and mitral cells, 5HT-IR fibers were seen along the border of glomerular units. Experimental lesion of the olfactory nerve was used to determine the origin of 5HT-IR fibers rostral to the olfactory bulb. The loss of these fibers and their reappearance during outgrowth of olfactory receptor neurons inferred that they emanate from the cell bodies in the olfactory sac. The results from this study suggest that axons of olfactory receptor neurons in larval lampreys receive modulation by 5HT from these neuronal fibers.

5-HT is present in nerves of guinea pig sphincter of Oddi and depolarizes sphincter of Oddi neurons.

This study involved immunohistochemistry and intracellular electrophysiology to investigate serotonergic neurotransmission in the sphincter of Oddi (SO). 5-Hydroxytryptamine (HT)-positive neurons (14 cells/preparation) and nerve fibers were observed in the ganglionated plexus. Serotonergic nerve fibers, which persisted under 2- to 6-day organ culture, were densely distributed, with varicose endings encircling some SO neurons. When 5-HT was applied to SO neurons, it elicited three different responses: 1) a fast depolarization to 5-HT in 31 of 62 cells was mimicked by 2-methyl-5-HT and blocked by LY-278584 (1 microM); 2) a prolonged depolarization to 5-HT in 21 of 62 cells evoked an increase in input resistance and was attenuated by the 5-HT1P antagonist renzapride (1 microM) but not by the 5-HT4 antagonist SDZ-205557 (0.1-10 microM); and 3) an indirect depolarization blocked by TTX or atropine was observed in 32 of 62 cells. 5-HT superfusion elicited a dose-dependent monophasic depolarization (EC50 = 2 microM, n=14). In conclusion, 5-HT is present in nerves of the SO and elicits both 5-HT3 and 5-HT1P receptor-mediated depolarizations, supporting the concept that 5-HT plays a role in SO regulation.

Serotonergic neurons are present and innervate blood vessels in the olfactory bulb of the laboratory shrew, Suncus murinus

The distribution and characteristics of serotonin-immunoreactivity in the olfactory bulb of the laboratory shrew (Suncus murinus, insectivore) was studied immunohistochemically. Serotonergic neurons were found only in the subependymal layer of the main olfactory bulb. These neurons were 8–12 μm in size and bipolar in shape. These serotonergic neurons had smooth nerve fibers which innervate blood vessels located mainly in the subependymal layer of the main olfactory bulb. On the other hand, other serotonergic nerve fibers with varicosities, which must be extrinsic, were detected in most olfactory layers except the olfactory nerve layer. This result suggests that intrinsic serotonergic neurons may control blood vessels and varicose serotonergic nerve fibers may act to modulate the olfactory transmission.

Serotonergic innervation of the supraependymal neuronal complex of the golden hamster

A ganglion-like system of intraventricular neuronal perikarya and processes known as the supraependymal neuronal complex (SENC) is located on the floor of the third ventricle of the golden hamster. Serotonergic neuronal elements were identified in the SENC by immunocytochemical techniques. Serotonin (5-hydroxytryptamine, 5-HT) was not detected within supraependymal neuronal perikarya. However, serotonergic nerve fibers were found to project via the median eminence both onto the surface and into the neuropil of the SENC. The SENC is thought to be involved in neuroendocrine regulation since it innervates the pituitary gland. The results of the present study suggest that serotonin plays a role in SENC/pituitary gland interaction.

Immunocytochemical identification of serotonergic supraependymal nerve fibers in the third ventricle of the house musk shrew, Suncus murinus

Supraependymal fibers of the house musk shrew (Suncus murinus) were examined by conventional scanning electron microscopy (SEM), backscattered electron (BSE) imaging of enzyme immunohistochemistry and by immunotransmission electron microscopy in the dorsal part of the third ventricular wall. In this region, ependymal cells were not so heavily ciliated and conventional SEM studies showed two main categories of supraependymal fibers. The first type consisted of long fibers fasciculated which were distributed over the ventricular surface between the anterior commissure and the subfornical organ. The second category was a thin fiber which was observed on the ependymal luminal surface. Some of these fibers had varicoses or terminal-like swellings. This type of supraependymal fiber seemed to originate in the first type of fiber bundles. To confirm the nature and the distribution of serotonin-immunoreactive supraependymal fibers, BSE imaging using immunohistochemical reactions was used. Serotonin-immunoreactive structures were shown as highlighted structures by means of a backscattered electron mode. These investigations revealed that the majority of both types of supraependymal fibers observed by conventional SEM contained serotonin. A moderate number of serotonergic supraependymal fibers was observed on the ventricular surface of the subfornical organ. Immunohistochemical studies using Vibratome sections of identical ventricular regions revealed the presence of serotonin-immunoreactive processes, with the use of light- and electron-microscopy. They were distributed in in the third ventricle just adjacent to the ependymal luminal surfaces. These fibers contained immunoreactive large cored vesicles and immunonegative small clear vesicles.