Adrenergic innervation of the gills of brown and rainbow trout,Salmo trutta and S. gairdneri

The adrenergic innervation of structures in the gills of brown and rainbow trout was studied with catecholamine fluorescence histochemistry. In the arterio-arterial vascular pathway, there was an innervation of the afferent and efferent lamellar arterioles, but the afferent and efferent filamental arteries and the secondary lamellae were devoid of any fluorescent nerve fibres. In S. trutta only, there was an additional innervation of the afferent and efferent branchial arteries and the base of the efferent filamental artery. The innervation of the arterio-venous vascular pathway was similar in both trout species. Many fluorescent nerve fibres were found on nutritive arterioles in the gill arch and interbranchial septum, and in the core of each filament between the surface epithelium and the wall of the filament venous sinus. No fluorescent nerve fibres were observed at the origins of the capillaries arising from the efferent filamental artery. The sympathetic nerve supply is provided to the gills mainly through the posttrematic nerve, with an occasional small contribution through the pretrematic nerve. The presence of adrenergic nerves in the gills is discussed in relation to the regulation of blood flow through the arterio-arterial and arterio-venous pathways.     

Autonomic innervation of the ocular choroid membrane in the chicken

Summary The distribution pattern of adrenergic fibres innervating the ocular choroid membrane of the chicken was studied by means of fluorescence and electron microscopy. In addition, the origin of these fibres was investigated after superior cervical ganglionectomy. Adrenergic axons reach the choroid, partly forming the perivascular plexuses and partly running in the choroid nerves and the choroidal branches of the ciliary nerves. The axon terminals distribute to the smooth muscle cells of the arterial wall and to the extensive system of smooth muscle cells of the intervascular stroma. After unilateral ganglionectomy, fluorescent fibres almost completely disappeared, and degenerative changes could be observed in the terminal varicosities on both smooth muscle cell populations. These findings suggest that the adrenergic axons either originate from neurones within the ipsilateral superior cervical ganglion, or pass through this ganglion. The persistence of normal terminals in short- and long-term ganglionectomised animals shows that the vasal and intervascular muscle cells of the choroid membrane are provided with both an adrenergic and a cholinergic innervation.This work was supported by grant No 80.00442.04 from the Italian National Research Council (CNR)     

A comparative study of the adrenergic nerves to the anterior eye segment of some primates

Summary The distribution of adrenergic terminals to the anterior eye segment of humans, Cynomolgue monkeys, squirrel monkeys, owl monkeys, Cebus monkeys, vervets, tamarins, and baboons has been investigated. The cornea is normally devoid of adrenergic terminals, except in a plexus near the limbus. The trabecular meshwork contains varying numbers of adrenergic terminals: usually none in Cynomolgus monkeys, patas monkeys, vervets, and humans, although fibres have very rarely been observed in Cynomolgus monkeys, vervets, and humans; a few in owl monkeys, squirrel monkeys, and tamarins; and moderate numbers in Cebus monkeys and baboons. From the evidence, however, it seems premature to presume an adrenergic innervation of the trabecular mechanism regulating the outflow resistance. The dilatator pupillae is regularly supplied with numerous adrenergic terminals and in the iris stroma there is probably an adrenergic innervation of the melanophores. The sphincter pupillae regularly contains adrenergic terminals with notable species differences; most fibres occur in baboons and fewest in humans, with the remaining species forming a middle class. The ciliary processes in all species contain a moderate number of adrenergic terminals, presumably primarily associated with the epithelium. Intraepithelial adrenergic terminals have been observed on the pars plana of the ciliary body of humans, Cebus monkeys, vervets, baboons, and patas monkeys. The ciliary muscle of baboons and Cynomolgus monkeys contains numerous adrenergic terminals. Moderate numbers occur in Cebus monkeys and vervets, and still less in (in falling order) tamarins, squirrel monkeys, humans, and patas monkeys.     

The intrinsic myenteric innervation of the hind-gut and accessory muscles of defaecation in the cat

Summary The anatomy and intrinsic innervation of the colon, rectum, internal anal sphincter, ano-coccygeus and recto-coccygeus have been studied in the cat with cholinesterase and catecholamine-fluorescence histochemical techniques. A variable pattern of intrinsic innervation by acetylcholinesterase-positive and adrenergic nerves along the length of the large bowel is described and is related to segmental variations in motor activity. A variation in the distribution of non-specific cholinesterase within the muscle layers is also described. Adrenergic nerves in proximal colon are arranged in the usual peri-ganglionic manner but there is also a rich direct adrenergic innervation of the longitudinal muscle in distal colon and rectum, and of circular muscle in lower rectum and internal anal sphincter. This distribution has not been reported in other species. Direct adrenergic innervation of muscle cells has been confirmed at ultrastructural level after treatment with 5-hydroxydopamine. Adrenergic neurones have not been detected in cat bowel. The ano- and recto-coccygeus muscles and internal anal sphincter possess a dense innervation of adrenergic and cholinesterase-positive nerves. It is suggested that the variation in intrinsic innervation along the large bowel should be considered in the interpretation of pharmacological and physiological experiments on this part of the gut.This work was supported by a grant from the King's College Hospital Voluntary Research Trust. We wish to thank Dr. J. P. Tranzer and F. Hoffman-La Roche & Co. Ltd., Basle, for the gift of 5-hydroxydopamine.We also thank Miss M. K. Egan and Mr. K. J. Davies for their technical assistance.     

The adrenergic innervation of the pulmonary vasculature,the lung and the thoracic aorta,and on the presence of aortic bodies in the domestic fowl (Gallus gallus domesticus L.)

Summary The Falck-Hillarp technique for the localisation of biogenic amines has been used to examine the adrenergic innervation of the thoracic vasculature and lung, and to demonstrate the occurrence of aortic bodies in the domestic fowl. The proximal pulmonary vein is very densely innervated but distally the innervation becomes sparse. The pulmonary artery is sparsely innervated over its whole length. The bronchial muscle of the lung has little adrenergic innervation and fluorescent cell bodies are absent from the lung. The thoracic aorta receives a moderate adrenergic innervation. In the region of the aortic arch and pulmonary arteries groups of fluorescent cells are common. Extramedullary chromaffin cells and small, intensely fluorescent cells occur within these groups. In the media of the aorta and pulmonary artery other types of fluorescent cells are found. These results are discussed in the light of previous observations.Part of this work was performed while the author was a postdoctoral research fellow of the National Heart Foundation of Australia. His thanks are due to Prof. G. Burnstock for use of laboratory facilities.     

Fluorescent histochemical studies on the mucosa of the vertebrate gastrointestinal tract

Summary Fluorescent histochemical studies have been made on the mucosa of the gut of a mammal (guinea-pig) and of some lower vertebrates (trout, eel, toad and lizard). Adrenergic nerves in the mucosa generally occur in perivascular plexuses. There appears to be no adrenergic innervation of the muscularis mucosae.Yellow fluorescent enterochromaffin cells were observed in the mucosal epithelium of all species, including fish. Autofluorescent structures in the mucosa of these animals have also been described and were particularly prominent in the large intestines of teleost fish.     

Adrenergic innervation of the gut musculature in vertebrates

Summary The adrenergic innervation of the gut musculature has been compared in various vertebrates (two teleost fish, an amphibian, a reptile and a mammal) by the fluorescent histochemical localization of certain monoamines. Very few, if any, adrenergic nerves occur within the longitudinal gut muscle of any of these animals, except for the taenia coli of the guinea-pig caecum. In contrast, the circular smooth muscle coat is supplied by varicose adrenergic nerves. These nerve fibres are particularly numerous in the toad large intestine, guinea-pig caecum, and throughout the eel gut, but are generally sparse or absent from the musculature of the stomach and small intestine of the trout, toad, lizard and guinea-pig. The extent of adrenergic innervation of the muscle has been discussed in relation to the physiology of the different muscle coats and to the general structure of the enteric plexuses in the vertebrate gut.     

Catecholamine- and acetylcholinesterase-containing nerves in human lower respiratory tract

Summary The innervation of human lower respiratory tract was studied with special emphasis on airways with sodium-potassium glyoxylic acid (SPG) and acetylcholinesterase (AChE) methods to demonstrate catecholamine-containing and acetylcholinesterase-containing nerve fibers. AChE-method revealed a rich network of cholinesterase positive nerves both inside the bronchial glands where they run around and between the acini, and the airway smooth muscle from secondary bronchi to terminal bronchioli. No AChE-positive fibers were found in connection with the blood vessels or within the epithelium of bronchi or bonchioli. The AChE-positive nerve fibers in bronchial smooth muscle greatly outnumbered those containing catecholamine. The SPG-method revealed the presence of adrenergic nerves from the level of secondary bronchi to that of terminal bronchioli. These nerve fibers were most abundant in bronchial glands, where their amount was equal and distribution similar to those of AChE-containing nerve fibers. Outside the glands adrenergic fibers were constantly seen in connection with the bronchial blood vessels in connective tissues surrounding bronchi. A few nerve fibers were also present in airway smooth muscle from the secondary bronchi to terminal bronchioli.     

Adrenergic Nerves in the Avian Eye and Ciliary Ganglion

Summary The distribution of adrenergic fibres to the eye and to the ciliary ganglion was studied in pigeons, chicken and ducks with the aid of the sensitive and highly specific fluorescence method of Falck and Hillarp. In some animals the intensity of the fluorescence was increased by treating the animals with Nialamide and 1-DOPA. The cornea contained no adrenergic fibres except at the limbus, where a plexus of adrenergic varicose fibres was seen, partly associated with vessels. In the chamber angle, adrenergic varicose fibres were common in the loose connective tissue covering the canal of Schlemm. The canal of Schlemm was supplied by only few adrenergic fibres, but such fibres appeared along the intrascleral aqueous drainage vessels. In the iris, adrenergic varicose fibres appeared immediately in front of the posterior layer of pigment cells, strongly indicating the presence of a dilator homologous with that seen in mammals. The frontal third of the stroma contained several adrenergic varicose fibres, many of which seemed to lack association with any vessel. Varicose adrenergic fibres were also sparsely seen in the striated muscle of the iris. The ciliary processes contained many adrenergic varicose fibres, at least part of which seemed to be associated with the ciliary epithelium. The striated muscles of the ciliary body contained adrenergic varicose fibres along the vessels only. The retina contained adrenergic varicose fibres in three layers in the inner plexiform layer. Adrenergic ganglion cells of two sizes were detected in the inner nuclear layer. The retinal vessels had no adrenergic nerve fibres. The pecten was also devoid of adrenergic nerve fibres, except along the vessels close to the papilla. The optic nerve contained adrenergic varicose nerve fibres along vessels only. In the ciliary ganglion, varicose adrenergic fibres appeared at the small ganglion cells, often forming baskets of synaptic character.Acknowledgements. The work has been supported by the United States Public Health Service (grant NB 06701-01), by the Swedish Medical Research Council (project B 67-12 X-712-02 A) and by the Faculty of Medicine, University of Lund, Sweden.     

On Sympathetic Innervation of Muscle Spindles of the Frog Rana temporaria

The work is concerned with solution of a questionable problem, whether there exists a direct sympathetic innervation of muscle spindles. On the isolated total preparations of muscle spindles, with the aid of a specific histochemical fluorescent method using glyoxylic acid, revealed is the sympathetic innervation of these structures: adrenergic terminal axons were found both on the intrafusal muscular fibers and the blood vessels supplying the receptor.     

Monoaminergic mechanisms in the nervous system of Lumbricus terrestris (L.)

Summary The localization and intraneuronal distribution of the monoaminergic transmitters in the nervous system of the earthworm, Lumbricus terrestris, have been investigated in detail with the aid of the histochemical fluorescence method of Falck and Hillarp.In the ventral nerve cord, many yellow fluorescent, 5-hydroxytryptamine containing neurons are found, but only few green fluorescent noradrenaline containing cell bodies, which, however, are numerous in the peripheral nervous system. There is an abundance of both fibre types in the neuropile.The 5-hydroxytryptaminergic neurons probably have a motor (possibly inhibitor) function; the adrenergic neurons in the body segments are supposed to have a receptor (exteroceptive and possibly proprioceptive) function.In the cerebral ganglion, both 5-hydroxytryptamine and noradrenaline containing neurons are found in large numbers, and there are closely packed numerous fibres of both types in the neuropile. Their function is more obscure, though an associative function can be presumed for some adrenergic neurons; smaller 5-hydroxytryptaminergic neurons might have a motor (perhaps inhibitor) function.Adrenergic sensory cells are found in the body integument, most frequently in the clitellum segments, in the prostomium, and in the roof of the buccal cavity. These cells give off varicose fibres that form a basi-epithelial network which is in communication with the green fluorescent sensory fascicles in the ventral nerve cord via the epidermal nerves, the ring nerves, and the segmental nerves. No direct adrenergic sensory-effector innervation of either circular and/or longitudinal musculature or gland cells seems to exist. No adrenergic free nerve endings in the body integument have been observed. Instead, there must be a synaptic contact with the motoneurons, either directly in the neuropile or via an interjacent neuron.No synaptic contacts have been observed in the ventral nerve cord between adrenergic or 5-hydroxytryptaminergic fibres and either the giant fibres or fluorescent or nonfluorescent perikarya.An adrenergic innervation of the pharynx musculature has been found, and sensory cells of a different type are present in and below the epithelium; here, a direct senso-motoric innervation of the pharyngeal musculature cannot be excluded. It is established that the adrenergic neurons in the stomatogastric nervous system have an exciting function on the pharynx, whereas a direct monoaminergic influence of the muscular movements of the intestine probably does not exist.Abbreviations Used A adrenaline - CA catecholamine - DA dopamine - 5-HT 5-hydroxytryptamine - MA monoamine - NA noradrenaline The research reported in this document has been sponsored by the Air Force Office of Scientific Research under Grant AF EOAR 67-15 through the European Office of Aerospace Research (OAR), United States Air Force, by the Swedish Natural Science Research Council (99-34, 6627), and by the Swedish Medical Research Council (B67-12X-712-02A).     

Histochemical studies of the microvascular effectors regulating blood supply to the cerebral cortex

The innervation of the pial arteries as well as the activity of enzymes (phosphorylase I, II, III, succindehydrogenase, lactate dehydrogenase, ATPase, GTPase and CTPase) responsible for vascular smooth muscle function were studied histochemically on total microscopic preparations of rabbit pia matter. An especially rich adrenergic and cholinergic innervation was found around the active microvascular effectors - sphincters of pial and precortical arterial off-shoots. The nerve fibers followed the radial arteries entering the cerebral cortex. No differences were detected between the pial arteries and active microvascular effectors in the enzyme activity.     

Functional and histochemical characterization of a uterine adrenergic denervation process in pregnant rats

The time course of pregnancy-induced changes in the contractile responses of isolated uterine rings and sympathetic innervation pattern were studied using electric field stimulation and histofluorescence techniques, respectively, in intact and 6-hydroxydopamine-treated rats. Neurally mediated contractions elicited by field stimulation (0.6 msec, 1-70 Hz, 40 V) were measured in uterine preparations obtained from nonpregnant, 6-hydroxydopamine-treated and 5-, 10-, 15-, 18-, and 22-day (term) pregnant rats. At all frequencies, the amplitudes of contractions were highest in nonpregnant uteri. Stimulation at 1-2.5 Hz evoked contractions in 10-day pregnant uteri but failed to cause contractions on Day 5 and from Day 15 onward. In uterine preparations obtained from term and from 6-hydroxydopamine-treated rats, contractions could not be evoked by stimulation at 1-20 Hz. Fluorescence histochemistry of uterine adrenergic nerves revealed rich perivascular and myometrial innervation in nonpregnant and in pregnant rats through Day 10. Degeneration and loss of adrenergic nerve fibers was apparent by Day 15, and fluorescent myometrial and perivascular nerves were practically absent by Day 22. These findings demonstrate a progressive, frequency-related reduction of nerve-mediated uterine contractions beginning in midterm pregnancy, in parallel with a gradual loss of adrenergic nerve fibers. Pregnancy-induced nerve degeneration may promote the development of nonsynaptic alpha-adrenergic uterine contractile activity towards term. The reduced responsiveness of uterine smooth muscle to electric field stimulation in early pregnancy appears to be unrelated to alterations in uterine innervation but may be related to changes associated with implantation.     

Innervation of skin glands in the frog

Summary A comparative study was undertaken on the innervation of mucous and granular glands in frog skin. Results obtained by the Falck-Hillarp fluorescence technique and cholinesterase staining indicated that both types of glands receive exclusively adrenergic innervation. Electron microscopy was used to investigate the innervation pattern at the ultrastructural level. The distribution of nerve terminals was found to differ in the two types of glands. In the mucous gland, terminals were found at a distance of about 0.5 m from the basement membrane but never within the gland parenchyma. In the granular gland, the terminals were located between smooth muscle cells and also in direct contact with the secretory epithelium but never outside the basement membrane.This work was carried out in part at King Gustaf V:s Forskningsinstitut, Stockholm, and was supported by a grant from Karolinska Institutet     

A comparative study of the adrenergic innervation of the teleost heart

Summary An adrenergic cardiac innervation has been found in the following teleost species:Platycephalus bassensis (Platycephalidae);Atopomycterus nicthemerus (Diodontidae);Aracana ornata (Ostraciontidae);Torquiginer glaber (Tetraodontidae);Aldrichetta forsteri (Mugilidae);Anguilla australis occidentalis (Anguillidae). In contrast, no evidence for an adrenergic cardiac innervation was found in the pleuronectid,Rhombosolea tapirina.Fluorescence histochemical studies indicated that adrenergic nerves in the sinus venosus and atrium entered via the vagus, whereas those to the ventricle passed mainly along the coronary vasculature. No fluorescent nerves were observed in the heart ofRhombosolea.Transmural stimulation of these adrenergic nerves increased the force of beat in the atrium and ventricle ofPlatycephalus, Atopomycterus andAracana, and in the atrium only ofTorquiginer, Aldrichetta andAnguilla. In addition stimulation of the abdominal vagus nerve in the presence of hyoscine increased the force of beat and heart rate in spontaneously beating sinus-atrium preparations of all species exceptRhombosolea. Applied catecholamines increased the force of beat and heart rate in the spontaneously beating heart of all species includingRhombosolea.     

Morphology of wing mechanoreceptors involved in the wing retraction reflex in the pteropod mollusc Clione limacina

Tactile stimulation of the wings (parapodia) of actively swimming Clione limacina results in inhibition of swimming and retraction of the wings. Electrophysiological evidence suggests that wing mechanoreceptors have central cell bodies and wide innervation fields in the ipsilateral wing. Scanning electron microscopy of expanded wings reveals ciliary cone processes arranged in a pattern that is similar to the electrophysiologically‐determined innervation fields of wing mechanoreceptors. Transmission electron microscopy suggests that the ciliary cone structures are terminal processes of neuron‐like cells. Three‐dimensional reconstructions of serially‐sectioned terminal processes indicate that cell bodies are not found in the wing epithelium or immediately under the epithelium, further supporting the notion that the wing mechanoreceptors have central cell bodies.     

Adrenergic innervation of the smooth muscle cells of the cauda epididymis of the mouse

The adrenergic innervation in the smooth muscle of the cauda epididymidis of the mouse was investigated by a fluorescence technique using glyoxylic acid and by electron microscopy. As in other species, this innervation is well developed in the terminal segment of the epididymis. It varies according to muscular type: the small myocytes of the proximal zone of the tail have a visceral contractile innervation, while for the typical muscle of the distal region, the pattern is a multiple-unit one. In the mouse, the nexus are more numerous than in man and in the monkey, and constitute a facilitating factor.     

The origin and distribution of adrenergic nerve fibres in the guinea-pig colon

Summary A detailed study of the origin and distribution of sympathetic fibres in the distal colon of the guinea-pig has been made using the fluorescent histochemical method for localizing catecholamines. The extrinsic adrenergic fibres of the colonie sympathetic nerves follow the inferior mesenteric artery and its branches to the colon. Some of the extrinsic adrenergic fibres are associated with the parasympathetic fibres of the pelvic nerves near the colon. Complete adrenergic denervation follows the removal of the inferior mesenteric ganglion or the destruction of the nerves running with the inferior mesenteric artery.No fluorescent fibres, other than those associated with blood vessels, were observed in air-dried stretch preparations of the isolated longitudinal muscle. However, a substantial number of varicose, terminal fibres, not associated with blood vessels, were observed in the circular muscle. Some varicose fibres, apart from those associated with ganglion cells, were observed in the myenteric plexus. These fibres were seen in the bundles of nerves running between the nodes of the plexus and also as single fibres which branched from the plexus to end in areas free of ganglion cells.Three plexuses of adrenergic nerve fibres have been distinguished in the submucosa: a dense plexus of terminal fibres innervating both the veins and arteries; a plexus consisting of innervated nodes of ganglion cells, connected by bundles of fluorescent and non-fluorescent nerves; and a plexus of varicose and non-varicose fibres, which is not associated with ganglion cells. Some groups of ganglion cells in the submucosa were without adrenergic innervation.A plexus of varicose fibres forms a meshwork in the lamina propria of the mucosa. The muscularis mucosae is sparsely innervated. Most of the blood vessels in the mucosa are not associated with adrenergic fibres.     

Cholinesterases and choline acetyltransferase in the ductus deferens of the guinea-pig

Summary Several authors have reported that longitudinal and circular muscle layers of the guinea-pig ductus deferens possess a rich adrenergic innervation. Cholinergic innervation has been doubted by several authors, especially its presence in the longitudinal muscle layer. Acetylcholinesterase and butyrylcholinesterase were demonstrated, by electronmicroscopic examination of both muscle layers of the guinea-pig ductus deferens, to be localized on the axolemma of the nerve endings and in smooth-muscle fibres, on sarcolemma, in the intracellular caveolae and in the intercellular space. Activity of cholinesterases and choline acetyltransferase was measured by the radiometric method and was found in both muscle layers. The activity of butyrylcholinesterase was higher than that of acetylcholinesterases in the homogenates of the whole ductus deferens and in the longitudinal muscle layer. In the circular muscle layer, the activity of acetylcholinesterase was higher than the activity of butyrylcholincsterase. In both muscle layers, we also found choline acetyltransferase, the activity being stronger in the circular layer. The localization of cholinesterases in smooth-muscles in the same places as the calcium and muscarinic acetylcholine receptors is discussed, together with the possibility that the enzyme is in some way involved in the excitation-contraction mechanism of smooth muscle.Part of this work was presented at the 2^nd International Meeting on Cholinesterases, Bled, Yugoslavia, 1983     

Uterine adrenergic and cholinesterase-positive nerves and myometrial catecholamine concentrations during pregnancy in sheep

Uterine adrenergic and cholinesterase (AChE)-positive innervation of the sheep uterus during anestrus and at 4 stages of pregnancy were examined by histochemical methods. In addition, uterine and cervical myometrium concentrations of norepinephrine (NE) and dopamine (DA) were determined using high-performance liquid chromatography. During anestrus, adrenergic and AChE-positive nerve fibers in the uterine myometrium and endometrium were primarily associated with the vasculature. Innervation of myometrial smooth muscle was almost exclusively by adrenergic fibers. In the endometrium, fibers of both types were observed closely associated with endometrial glands, and adrenergic fibers were observed in the connective tissue beneath the luminal epithelium. Density of uterine innervation decreased by day 65 of pregnancy with an additional decrease by day 105. Myometrial NE concentrations were higher in the cervix than the uterus. Uterine NE concentrations generally were not affected by pregnancy. Although cervical NE per gram of tissue decreased during pregnancy, this effect of pregnancy was not detected when NE was expressed per microgram of DNA. Myometrial DA concentrations were higher in uterine segments than in the cervix. DA concentrations decreased during pregnancy in all tissues except the posterior uterine segment. The DA to NE ratio in the uterus was greater than that for the cervix and was not generally affected by the stage of pregnancy. These results demonstrate that cholinergic and adrenergic nerves supply the sheep uterus. Decreasing fiber density during pregnancy suggests that a majority of the innervation to the sheep uterus is supplied by 'short' nerve fibers whose activity is regulated by steroids of pregnancy. The possible role of DA as a neurotransmitter in the sheep uterus is discussed.