The autonomic innervation of the ovary of the dab,Limanda yokohamae

The autonomic innervation of the ovary of the dab was studied histologically and physiologically. The ovary receives a branch of nerve bundles that emerge into the abdominal cavity at the postero-ventral end of the kidney and can be traced back to the sympathetic chain in the vicinity of the 5th vertebra. Almost all the nerve fibers are AChE-positive, and some of them also emit adrenergic fluorescence. Electrical stimulation of the ovarian nerves caused ovarian contractions, and administration of ACh elicited contractions of the ovary preparations, supporting the hypothesis that the ovary is innervated by excitatory cholinergic fibers. In the ovarian nerve bundles, many AChE-positive and non-fluorescent ganglion cells are scattered. Ultrastructural studies suggest that nerve endings situated on the ovarian smooth muscle and on ganglion cells are cholinergic. These results also suggest that the cells are the post-ganglionic neurons of the cholinergic innervation and the axons of the cells reach to the muscle cells. On the other hand, the adrenergic fluoresecent fibers possibly participate in the inhibitory innervation, since the presence of inhibitory beta-adrenoceptors were demonstrated by pharmacological studies.     

Monoamine storage in relation to cardiac regulation in the port jackson shark heterodontus portusjacksoni

Summary A study has been made of catecholamine stores that may be involved in cardiac regulation in the shark Heterodontus portusjacksoni. The anatomy of the anterior chromaffin bodies associated with the sympathetic chain is described. A fluoresent histochemical study shows that the chromaffin cells contain a monoamine, probably noradrenaline. The chromaffin cells have a fine structure comparable to that of chromaffin cells in other vertebrates. The heart is devoid of histochemically-demonstrable chromaffin cells or adrenergic nerve fibres, with the exception of a very sparse adrenergic innervation of the sinus venosus. It is argued that adrenergic control of the heart in Heterodontus might occur via amines released from the anterior chromaffin masses into the blood in the posterior cardinal sinus, which is then aspirated directly into the heart.     

Distribution and origin of vasoactive intestinal polypeptide (VIP)-immunoreactive,acetylcholinesterase-positive and adrenergic nerves of the cerebral arteries in the bent-winged bat (Mammalia: Chiroptera)

Summary The overall distribution and origins of vasoactive intestinal polypeptide (VIP)-immunoreactive (IR), acetylcholinesterase (AChE)-positive and adrenergic nerves in the walls of the cerebral arteries were investigated in the bent-winged bat. VIP-IR and AChE-positive nerves innervating the bat cerebral vasculature appear to arise mainly from VIP-IR and AChE-positive cell bodies within microganglia found in the nerve bundle accompanying the sympathetic nerve bundle within the tympanic cavity. These microganglia, as well as the nerve bundle containing them, do not emit catecholamine fluorescence, suggesting that they are of the cranial parasympathetic outflow, probably the facial or glossopharyngeal one. The axons from VIP-IR and AChE-positive microganglia run intermingled with sympathetic adrenergic nerves in the same thick fiber bundles, and reach the cranial cavity through the carotid canal. In addition, some of the VIP-IR fibers innervating the vertebro-basilar system, at least the basilar artery, originate from VIP-IR nerve cells located in the wall of this artery.The supply of VIP-IR fibers to the bat major cerebral arteries is the richest among mammals that have been studied, and differs from other mammals in that it is much greater in the vertebro-basilar system than in the internal carotid system: plexuses of VIP-IR nerves are particularly dense along the walls from the posterior ramus to posterior cerebral and basilar arteries. Small pial and intracerebral arteries of the vertebro-basilar system, especially those of the posterior cerebral artery which supply most parts of the diencephalon and cerebrum, are also richly innervated by peripheral VIP-IR fibers. This pattern corresponds well with the innervation pattern of adrenergic and AChE-positive nerves.     

Annexin II in exocytosis: catecholamine secretion requires the translocation of p36 to the subplasmalemmal region in chromaffin cells

Annexin II is a Ca(2+)-dependent membrane-binding protein present in a wide variety of cells and tissues. Within cells, annexin II is found either as a 36-kD monomer (p36) or as a heterotetrameric complex (p90) coupled with the S-100-related protein, p11. Annexin II has been suggested to be involved in exocytosis as it can restore the secretory responsiveness of permeabilized chromaffin cells. By quantitative confocal immunofluorescence, immunoreplica analysis and immunoprecipitation, we show here the translocation of p36 from the cytosol to a subplasmalemmal Triton X-100 insoluble fraction in chromaffin cells following nicotinic stimulation. A synthetic peptide corresponding to the NH2-terminal domain of p36 which contains the phosphorylation sites was microinjected into individual chromaffin cells and catecholamine secretion was monitored by amperometry. This peptide blocked completely the nicotine-induced recruitment of p36 to the cell periphery and strongly inhibited exocytosis evoked by either nicotine or high K+. The light chain of annexin II, p11, was selectively expressed by adrenergic chromaffin cells, and was only present in the subplasmalemmal Triton X-100 insoluble protein fraction of both resting and stimulated cells. p11 can modify the Ca(2+)- and/or the phospholipid-binding properties of p36. We found that loss Ca2+ was required to stimulate the translocation of p36 and to trigger exocytosis in adrenergic chromaffin cells. Our findings suggest that the translocation of p36 to the subplasmalemmal region is an essential event in regulated exocytosis and support the idea that the presence of p11 in adrenergic cells may confer a higher Ca2+ affinity to the exocytotic pathway in these cells.     

Characterization of Two Chromaffin Cell Populations Isolated from Bovine Adrenal Medulla

Cultures of chromaffin cells isolated from the bovine adrenal medulla have been extremely useful for investigating secretory mechanisms, but such cultures used up to the present time represent mixed populations of adrenergic and noradrenergic cells. This report describes how, with slight modifications to standard procedures, two separate chromaffin cell populations may be separated from bovine adrenal medullae. These two cell fractions have been characterized by biochemical, immunocytochemical, and morphological techniques as enriched populations of adrenergic or noradrenergic cells, respectively. The adrenergic cell-enriched fraction consists of greater than 90% adrenergic cells, whereas the noradrenergic cell-enriched fraction contains greater than 60% noradrenergic cells. We also demonstrate that these cells may be cultured with their secretory machinery intact: analysis of secreted catecholamines from nicotine- or high K+ concentration-stimulated cells cultured from each fraction confirms that adrenaline is the major catecholamine secreted by one fraction, whereas noradrenaline is mainly secreted by the other.     

Studies on the interactions between nerve fibres from para-and orthosympathetic ganglia and adreno-cortical and -medullary cells in joint culture

The interactions between nerve fibres from para- and orthosympathetic ganglia and adreno-cortical and -medullary cells were studied in joint cultures using explanted guinea-pig ciliary and sympathetic chain ganglia and enzyme-dispersed rat adrenal gland cells. Nerve fibres from both para- and orthosympathetic ganglia made only transitory contact with cortical cells, but consistently formed associations with isolated chromaffin cells which lasted for up to 10 days. Contacts between axons and chromaffin cells often showed particularly large varicosities and frequently withstood severe tests of durability from pulls of the fibre or the cell or both. By correlating phase contrast and catecholamine histochemistry (Falck-Hillarp method) it was shown that sympathetic fibres forming long-lasting contacts with chromaffin cells were adrenergic. The functional implications of the ability of autonomic nerves to distinguish between adreno-cortical and -medullary cells and the lack of specificity shown by the para- and orthosympathetic neurons during formation of long-lasting associations with chromaffin cells are discussed.     

Morphological and functional characterization of beige mouse adrenomedullary secretory vesicles

We tested whether the giant secretory granules observed in the mast cells of the naturally occurring mutant beige mouse (BM) (C57BL/6N-bg) were also present in the adrenal chromaffin cells. The presence of large chromaffin granules (CG) would be a valuable tool for the study of exocytosis in neuronal tissues. Conversely, the observation of large vesicles within chromaffin cells that are different from CG could indicate that CG are of a different origin than granules of mast cells. Ultrastructural analysis demonstrated the presence of large lysososmal-like vesicles in the BM, and also a discrete increase in the number of CG with diameters larger than 240 nm but not of giant CG. In addition, amperometric measurements of single-event exocytosis, using carbon fiber microelectrodes, showed no differences between the quantal size of secretory events from BM and wildtype or bovine chromaffin cells. Minor but significant differences were found between the kinetics of exocytosis in BM cells andwild-type mouse cells. We conclude that CG, but not the abnormal-sized vesicles found in BM chromaffin cells contribute to the catecholamine secretion and that abnormal secretory granules are not present in adrenergic cell lineage.     

Differential Expression of Syntaxin 1A and 1B by Noradrenergic and Adrenergic Chromaffin Cells

The expression and localization of syntaxin isoforms 1A and 1B in adrenergic and noradrenergic chromaffin cells were examined by both immunoblot analysis and confocal immunofluorescence microscopy. Syntaxin 1A was found in higher levels in noradrenergic cells, whereas syntaxin 1B was similarly expressed in most noradrenergic and adrenergic cells. However, some heterogeneity was observed within each catecholaminergic phenotype. Although the majority of adrenergic cells appeared to express low levels of syntaxin 1A, about 7% was strongly stained for syntaxin 1A. A subpopulation of noradrenergic cells, about 17%, expressed greater levels of syntaxin 1B. Syntaxin 1B labeling showed a punctate appearance in the cytoplasm, whereas syntaxin 1A appeared predominantly localized to the plasma membrane. These data show differences in the exocytotic machinery of the two subtypes of chromaffin cells that may underlie some of the distinct characteristics of adrenaline and noradrenaline secretion.     

Nonadrenergic modulation by clonidine of the cosecretion of catecholamines and enkephalins in adrenal chromaffin cells

Cultured bovine chromaffin cells cosecrete catecholamines and enkephalins following cholinergic nicotinic stimulation. Initial reports on the inhibitory effect of clonidine on catecholamine secretion raised the possibility of a modulation of chromaffin cell function through a presynaptic adrenergic mechanism. The purpose of this work was to investigate the pharmacological characteristics of this inhibitory effect of clonidine on the cosecretion of catecholamines and enkephalins in 4-day-old cultured chromaffin cells. We observed that clonidine completely inhibits nicotine-stimulated secretion of both leucine-enkephalin and catecholamines with an IC50 of 34 microM. Treatment of chromaffin cells for 3 days with 100 nM reserpine leads to a 67% increase in nicotine-stimulated secretion of leucine-enkephalin without any effect on the IC50 of clonidine. In reserpine-treated chromaffin cells, norepinephrine (100 microM) inhibits only by 27% nicotine-stimulated secretion of leucine-enkephalin with an IC50 of 50 microM. Neither the alpha 2-adrenergic antagonist yohimbine nor the alpha 1-adrenergic antagonist prazosin could fully reverse the inhibitory effect of clonidine on leucine-enkephalin secretion at 10 nM. These results tend to rule out the role of alpha-adrenergic receptors in the mediation of clonidine inhibition of cosecretion in chromaffin cells.     

The determination of the adrenal medullary cell fate during embryogenesis

One subset of neural crest cells, the sympathoadrenal precursors, undergoes a switch in phenotype expression, when they invade the adrenal anlagen and become associated with adrenocortical cells. To investigate the mechanisms responsible for the conversion of noradrenaline synthesizing precursors to adrenaline producing endocrine chromaffin cells we studied the role of glucocorticoids on the initial induction of adrenaline synthesis in embryonic adrenals and cultures of highly purified chromaffin precursor cells. We could show that in vivo differentiation of rat chromaffin precursors commences between 16.3 and 17.3 days of gestation. While adrenaline and the activity of the enzyme phenylethanolamine N-methyltransferase (PNMT), which converts noradrenaline to adrenaline, were present at Embryonic Day 17.3 (E17.3), they were not detectable in E16.3 adrenals. Small amounts of corticosterone were present in E16.3 adrenals and plasma, but in parallel with the initial induction of adrenaline biosynthesis, a sharp rise in organ and plasma glucocorticoid levels occurred until E17.3. Chromaffin precursor cells, isolated at E16.3 and cultured for 4 days, failed to express PNMT activity and adrenaline. However, 0.1 nM dexamethasone was already sufficient for the initial induction of adrenaline and its synthesizing enzyme. Specific glucocorticoid binding of freshly isolated chromaffin (precursor) cells revealed a developmental increase during embryogenesis, yet no glucocorticoid binding sites were detectable in chromaffin precursor cells at E16.3. They appeared at E17.3 in parallel with the initial induction of adrenaline biosynthesis and the enormous rise of adrenal and plasma corticosterone levels. We therefore conclude that glucocorticoids are essential and sufficient to trigger the differentiation of noradrenergic sympathoadrenal precursors to adrenergic chromaffin cells after a functional glucocorticoid receptor system has been established.     

Acetylcholine-induced calcium signalling in adrenaline- and noradrenaline-containing adrenal chromaffin cells

Adrenal chromaffin cells secrete catecholamines in response to cholinergic receptor activation by acetylcholine (ACh). Characteristics of Ca(2+) transients induced by activation of nicotinic (nAChRs) and muscarinic (mAChRs) receptors were analyzed using Fura-2 fluorescent measurements on rat chromaffin cells. We first found two populations of chromaffin cells, which differently responded on AChR stimulation. In the first group (n-cells), consecutive ACh applications evoked persistent Ca(2+) transients, whereas desensitizing transients were observed in the other group (m-cells). The AChR agonists and antagonists precisely imitated or abolished the ACh action on n- and m-type cells, respectively. Cytochemical staining showed that n-cells contained adrenaline, whereas m-cells-noradrenaline. Thus, for the first time we found that nAChRs and mAChRs are differentially expressed in adrenergic and noradrenergic chromaffin cells, respectively. Our data suppose that chromaffin cells can be differentially regulated by incoming ACh signals and in such way release different substances-adrenaline and noradrenaline.     

Differential contribution of syntaxin 1 and SNAP-25 to secretion in noradrenergic and adrenergic chromaffin cells

We used botulinum neurotoxins (BoNT) to examine whether differences in the secretory activity of noradrenergic and adrenergic chromaffin cells are related to differences in the exocytotic machinery of these two types of bovine adrenal medulla cells. Cleavage of syntaxin and SNAP-25 by BoNT/C1 decreased in a dose-dependent way the release of both noradrenaline and adrenaline, but noradrenaline release was more sensitive to BoNT/C1. Cleavage of SNAP-25 by BoNT/A also had a larger inhibitory effect on noradrenaline release than on adrenaline release. Neither BoNT/C1 nor BoNT/A affected the intracellular Ca2+ responses induced by K+-depolarisation, and the extent of the inhibition of K+-evoked catecholamine release by selective blockers of voltage-gated Ca2+ channels was not affected by BoNT/C1. Therefore, our data do not support the hypothesis of a regulatory effect of syntaxin or SNAP-25 on the activity of Ca2+ channels. The lower sensitivity of adrenaline release to BoNT was not due to a reduced ability of the toxins to enter or to cleave their protein targets in adrenergic cells, since immunoblot analysis showed the cleavage of a larger fraction of syntaxin 1A in adrenergic cells, as compared to the cleavage in noradrenergic cells. The immunoblot analysis also showed larger amounts of syntaxin 1A in noradrenergic chromaffin cells than in adrenergic cells. Thus, in spite of a greater cleavage of syntaxin 1A in adrenergic cells by BoNT/C1, adrenaline release was less sensitive to BoNT/C1, suggesting that the release process in noradrenergic cells might be more dependent on syntaxin 1A and SNAP-25, as compared to adrenergic cells.     

S100A10‐Mediated Translocation of Annexin‐A2 to SNARE Proteins in Adrenergic Chromaffin Cells Undergoing Exocytosis

In neuroendocrine cells, annexin‐A2 is implicated as a promoter of monosialotetrahexosylganglioside (GM1)‐containing lipid microdomains that are required for calcium‐regulated exocytosis. As soluble N‐ethylmaleimide‐sensitive factor attachment protein receptors (SNAREs) require a specific lipid environment to mediate granule docking and fusion, we investigated whether annexin‐A2‐induced lipid microdomains might be linked to the SNAREs present at the plasma membrane. Stimulation of adrenergic chromaffin cells induces the translocation of cytosolic annexin‐A2 to the plasma membrane, where it colocalizes with SNAP‐25 and S100A10. Cross‐linking experiments performed in stimulated chromaffin cells indicate that annexin‐A2 directly interacts with S100A10 to form a tetramer at the plasma membrane. Here, we demonstrate that S100A10 can interact with vesicle‐associated membrane protein 2 (VAMP2) and show that VAMP2 is present at the plasma membrane in resting adrenergic chromaffin cells. Tetanus toxin that cleaves VAMP2 solubilizes S100A10 from the plasma membrane and inhibits the translocation of annexin‐A2 to the plasma membrane. Immunogold labelling of plasma membrane sheets combined with spatial point pattern analysis confirmed that S100A10 is present in VAMP2 microdomains at the plasma membrane and that annexin‐A2 is observed close to S100A10 and to syntaxin in stimulated chromaffin cells. In addition, these results showed that the formation of phosphatidylinositol (4,5)‐bisphosphate (PIP₂) microdomains colocalized with S100A10 in the vicinity of docked granules, suggesting a functional interplay between annexin‐A2‐mediated lipid microdomains and SNAREs during exocytosis.     

Neurofilament Proteins in Cultured Chromaffin Cells

Antibodies were raised against the 200-kd, 145-kd, and 68-kd subunits of a rat neurofilament preparation. Immunoblots showed that each antibody was specific for its antigen and that it did not cross-react with any of the two other neurofilament polypeptides. Use of the three antibody preparations to stain bovine chromaffin cells in culture by the indirect immunofluorescence technique indicated that the three neurofilament polypeptides are present in chromaffin cells maintained in culture for 3 or 7 days. The three anti-neurofilament antibodies labelled the cells in a similar pattern: very thin filaments specifically localized around the nucleus were observed whereas neurites and growth cones, developed by cultured chromaffin cells, were generally not stained. Some fibroblasts were present in our cultures but they were never stained by any of the neurofilament antibodies. This indicated that the antibodies used do not react with vimentin, the major intermediate filament protein found in fibroblasts. The three neurofilament antibodies were also used to immunoprecipitate specifically three proteins of molecular weights 210 kd, 160 kd, 70 kd from solubilized extracts of cultured chromaffin cells that were radiolabelled with [35S]methionine. These proteins correspond in molecular weight to the neurofilament triplet found in bovine brain. Finally, the presence of neurofilaments in freshly isolated chromaffin cells was tested by immunoblotting using the 68-kd antibody. A 70-kd protein was specifically stained by this antibody, suggesting that neurofilaments are not only present in cultured chromaffin cells but also in the adrenal gland in vivo. It is concluded from these results that chromaffin cells contain completely assembled neurofilaments. This additional neuronal property again illustrates that chromaffin cells are closely related to neurons and therefore represent an attractive model system for the study of functional aspects of adrenergic neurons.     

Development of the sympathetic system in the Mexican axolotl, Ambystoma mexicanum

Migration of trunk neural crest cells in axolotl embryos has been followed by autoradiography using grafts of [³H]thymidine-labeled neural folds. Crest cells form melanocytes, dorsal fin mesenchymal cells, spinal ganglion cells, and reach the sympathetic region. Sympathetic neurons, however, are not identifiable morphologically until about 6 weeks posthatching, in 24-mm larvae. At this stage, neurons, although few, have characteristic ultrastructure and receive synapses. The diffuse ganglia also contain innervated chromaffin cells; these differentiate earlier, a few days posthatching, in 14-mm larvae. A third type of cell is of morphologically indifferent appearance. Catecholamine-specific formaldehyde-induced fluorescence first appears clearly at 14 mm; with growth, the number of fluorescent cells increases. Series of larvae were injected intraperitoneally with nerve growth factor (NGF), six 30-unit injections over 2 weeks. NGF treatment increases the number of neurons apparent in 24-mm larvae. Furthermore, differentiated neurons occur in NGF-treated 20-mm larvae (about 4 weeks posthatching), when there are none in controls. The early appearance of differentiated chromaffin cells and the relatively late appearance of differentiated sympathetic neurons suggest that adrenergic functions during the first few weeks of larval life are controlled humorally by the chromaffin cells, and that at 24 mm, neurons begin to provide faster, finer control.     

An evolutionary change in the muscle lineage of an anural ascidian embryo is restored by interspecific hybridization with a urodele ascidian

Anural ascidians do not develop into a conventional tailed larva with differentiated muscle cells, however, embryos of some anural ascidian species retain the ability to express acetylcholinesterase (AChE) in a vestigial muscle cell lineage. This study examines the number of AChE-positive cells that develop in the anural ascidian Molgula occulta relative to that in the closely related urodele (tailed) species, Molgula oculata. Histochemical assays showed that M. oculata embryos develop 36 to 38 AChE-positive cells, consistent with the number of tail muscle cells expressed in other urodele ascidians. In contrast, M. occulta embryos develop a mean of only 20 AChE-positive cells in their vestigial muscle lineage. Cleavage-arrested embryos of the anural species express AChE only in B-line blastomeres, showing that the vestigial muscle lineage cells are derived from the primary muscle lineage. Less than the expected number of AChE-positive B-line cells develop in cleavage-arrested anural embryos, however, implying that the allocation of primary muscle lineage cells is decreased. Eggs of the anural species can be fertilized with sperm of the urodele species resulting in the development of some larvae that contain a short tail and/or a brain melanocyte, specific features of urodele larvae. The typical urodele number of AChE-positive cells is restored in some of these hybrid embryos. Both primary and secondary muscle lineages are restored because cleavage-arrested hybrid embryos develop more AChE-positive cells in the B-line blastomeres and supernumerary AChE-positive cells in the A-line blastomeres. Hybrid embryos that develop the urodele complement of AChE-positive cells also form a tail and/or a brain melanocyte showing that restoration of muscle lineage cells is coupled to the development of other urodele features. AChE expression occurred in anural embryos with disorganized or dissociated blastomeres, indicating that AChE expression is determined autonomously. It is concluded that an evolutionary change in the allocation of larval muscle lineage cells occurs during development of the anural ascidian M. occulta which can be restored by interspecific hybridization with the urodele ascidian M. oculata.     

Ultrastructure of cholinergic innervation in the cirrhotic liver in guinea pigs. Neurohistochemical and ultrastructural study

Hepatic cirrhosis was induced in guinea pigs by ligation of the common bile duct and innervation of the liver was studied by fluorescence histochemistry (glyoxylic acid method), acetylcholinesterase (AChE) neurohistochemistry (modified Karnovsky and Roots method), and transmission electron microscopy. In control animals the adrenergic terminals showed connections with endothelial cells, hepatocytes and fat-storing cells, but no cholinergic terminals were evident. Cirrhosis was present 6 weeks after the bile duct ligation and marked fibrosis, accompanied by bile duct proliferation, was evident in the portal areas. Numerous AChE-positive nerve fibers traversed the collagenous bundles in the fibrotic areas, and cholinergic terminals formed close contacts with fibroblasts. Each axon terminal was found to contain numerous small coreless vesicles and AChE-reaction products were confirmed in the space between a nerve terminal and a fibroblast. In contrast, fluorescence adrenergic nerve fibers and their terminals remained unchanged. This study demonstrates that parasympathetic cholinergic innervation participates in some stages in the development of hepatic cirrhosis.     

The hypophysis controls expression of SNAP-25 and other SNAREs in the adrenal gland

SNAP-25 (Synaptosomal Associated Protein of 25 kDa), in association with two other SNARE (soluble NSF attachment protein receptor) proteins, syntaxin and Vesicle Associated Membrane Protein, VAMP, is implicated in regulated and constitutive exocytosis in neurones and neuroendocrine cells. Our previous studies have shown that it is expressed more by noradrenergic than adrenergic chromaffin cells in the rat adrenal gland. Since certain hormones under hypophyseal control play an essential role in determining chromaffin cell phenotype, the present study examined the effect of hypophysectomy on SNAP-25 expression. Hypophysectomy was found by immunoblotting and RT-PCR analysis to increase adrenal gland SNAP-25, syntaxin-1 and VAMP-2 levels, without modifying the relative expression of SNAP-25 isoforms: immunocytochemistry showed a dramatic increase in SNAP-25 expression in former adrenergic chromaffin cells. Since adrenal glucocorticoids are considerably reduced by hypophysectomy, the effect of corticosterone replacement therapy was investigated. This did not change levels of SNAP-25, syntaxin-1 or VAMP-2. SNARE expression was also unmodified in pheochromocytoma cells treated with a synthetic glucocorticoid. In contrast, subcutaneous injection of hypophysectomized rats with thyroid hormone decreased adrenal SNAP-25, demonstrating the potential importance of the pituitary-thyroid axis. The current data thus demonstrate that the hypophysis exerts an inhibitory control on adrenal gland SNARE proteins. They suggest that glucocorticoids are unlikely to be directly responsible for this but provide evidence that thyroid hormones are implicated in this phenomenon. The putative role of hormonal regulation on SNARE function is discussed.     

Adrenergic and cholinergic components of the innervation of the arteries of the base of the bird brain

By means of Falck's and Koelle's methods adrenergic and cholinergic structures were studied in the arteries in the cerebral basis of blue rock pigeons and of hens, white leghorn stock. The number of nerve transmitters was estimated per 1 mm2 of the vessel surface. The arteries of the basis in pigeon brain are surrounded with developed adrenergic and cholinergic nerve plexuses, their density decreasing in the following order: nasal branch of the internal carotid artery, middle, nasal cerebral and basilar arteries. A little more cholinergic transmitters occur on the middle cerebral artery, while on the other vessels, concentration of cholinergic and adrenergic fibers is equal. In hens, the density in the arrangement of adrenergic nerve transmitters is higher in the nasal branch of the internal carotid and in the nasal cerebral arteries than in the basilar artery. At the same time, chromaffin cells forming numerous conglomerations in some places are found on the latter. In pigeons, the density of adrenergic fibers arrangement on the arteries of the cerebral basis is higher than in hens.