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 CHOLINERGIC COMPONENT IN THE INNERVATION OF THE LONGITUDINAL SMOOTH MUSCLE OF THE GUINEA PIG VAS DEFERENS : The Fine Structural Localization of Acetylcholinesterase

Acetylcholinesterase (AChE) has been detected on the plasma membrane of about 25% of the axons in the longitudinal smooth muscle tissue of guinea pig vas deferens. These axons are presumably cholinergic. No enzyme was detected in the remaining 75% of axons. These axons are presumably adrenergic. The plasma membrane of the Schwann cells associated with the cholinergic axons also stained for AChE. Some axon bundles contained only cholinergic or adrenergic axons while others contained both types of axon. When a cholinergic axon approached within 1100 A of a smooth muscle cell, there was a patch of AChE activity on the muscle membrane adjacent to the axon. It is suggested that these approaches are the points of effective transmission from cholinergic axons to smooth muscle cells. Butyrylcholinesterase activity was detected on the plasma membranes of all axons and smooth muscle cells in this tissue.     

Development of innervation to the atrial myocardium of the rabbit

Summary The development of innervation to the atrial myocardium of rabbits from 20th day of gestation to 35 days postnatal was studied ultrastructurally by electron microscopy and by demonstration of catecholamines by histofluorescence. Special attention was directed to the first morphologic appearance of nerve fibers and terminals and the closeness of juxtaposition of terminals with myocardial cells. Adrenergic and cholinergic terminals were identified on the basis of their differential ability to take-up and store the false adrenergic neurotransmitter 5-hydroxydopamine. Adrenergic terminals were first encountered at 20 days of gestation whereas cholinergic terminals could not be positively identified until the 24th day of gestation. Throughout development adrenergic terminals were more numerous than cholinergic, about 71 % of the terminals encountered being adrenergic. Many terminals approach closely (20–30 nm) to the sarcolemma of the muscle cells of the atrium. In many instances adrenergic and cholinergic fibers travel together in the same nerve bundle and are closely apposed without intervening Schwann-cell cytoplasm. Such a relationship could allow peripheral interaction between these fibers in the myocardium.Supported in part by the Kentucky Heart Association, Human Development Studies Program of the University of Kentucky and DHEW Grant 1 RO1 HL 22226-01 HED from the National Heart, Lung and Blood Institute. The technical assistance of Merle Wekstein is appreciated     

Comparative ultrastructure of ureteric innervation

The distribution and structure of the ureteric nerves in a small series of mammals was compared with that previously demonstrated in the rat. There was marked interspecies variation in the extent to which the nerves penetrated the wall of the ureter and in the degree of development of the deep submucous plexus. In animals with a highly developed deep submucous plexus, terminal arterioles frequently passed through the muscle coat before breaking up into capillaries. These vessels were surrounded by a fine periarteriolar plexus and were accompanied in their course through the muscle coat by one or more branches of the adventitial nerves. Intramuscular nerves not related to arterioles contained few axons with terminals classifiable as either adrenergic or cholinergic, and in animals in which the muscle cells were arranged in fascicles rather than in sheets, the nerves were typically interfascicular in position. As in the rat, only the periarteriolar plexuses contained large numbers of adrenergic axons. Cholinergic axons were generally few, but were not uncommon in the deep submucous plexus when this was well-developed. The majority of the terminals encountered in the intramural nerves contained variable and usually small numbers of both clear and large dense-cored vesicles. The relationship between these terminals and those defined in the submucous nerves of the rat ureter was discussed and it was suggested that the marked variations in the diameter of the axons in the terminal areas and in the number of vesicles in the terminals were related to the effects of the mechanical and other derangements which occur during processing.     

Developmental changes in the neurotransmitter properties of dissociated sympathetic neurons: a cytochemical study of the effects of medium

Sympathetic principal neurons were dissociated from the superior cervical ganglia of newborn rats and grown in several culture conditions shown previously to affect the transmitter status of the neurons. In three of these conditions the neurons are known to develop adrenergic functions over a 3- to 4-week period; in a fourth condition, they develop predominantly cholinergic functions. In this ultrastructural study, the transmitter status of the neurons during development in the several different media was examined after permanganate fixation which causes a granular precipitate in synaptic vesicles containing norepinephrine (small granular vesicles or SGV). It was found that as early as 4 days after plating, synapses and varicosities were present. In all four conditions, all of the terminals contained numerous SGV, indicating that the neurons both synthesize and store norepinephrine. Under “adrenergic” growth conditions, the terminals remained adrenergic in appearance during further development. Under “cholinergic” conditions, terminals of cholinergic appearance were present as early as 7 days and their incidence increased with time. Although the cholinergic terminals contained little or no endogenous norepinephrine, many were initially able to take up and store exogenous catecholamine. These results indicate that the dissociated sympathetic neurons of newborn rats which survive in culture acquired adrenergic transmitter functions early. Under “cholinergic” culture conditions, the neurons lose the ability to synthesize detectable quantities of norepinephrine; the ability to take up and store detectable quantities of exogenous catecholamines disappears more slowly.     

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.     

Prejunctional beta 1-adrenoceptors inhibit cholinergic transmission in canine bronchi

The aim of the present study was to determine in canine bronchi the effects produced by norepinephrine (released from adrenergic nerve terminals) on cholinergic neurotransmission. Electrical stimulation of canine bronchi activates cholinergic and adrenergic nerve fibers. The adrenergic neuronal blocker, bretylium tosylate, inhibited the increase in [3H]norepinephrine overflow evoked by electrical stimulation but did not prevent that caused by the indirect sympathomimetic tyramine. During blockade of the exocytotic release of norepinephrine with bretylium, the pharmacological displacement of the sympathetic neurotransmitter by tyramine significantly decreased the contractions evoked by electrical stimulation but did not affect contractions caused by exogenous acetylcholine. Metoprolol, a beta 1-adrenergic antagonist, abolished and propranolol significantly reduced the effect of tyramine during electrical stimulation. alpha 2-Adrenergic blockade, beta 2-adrenergic blockade, or removal of the epithelium did not significantly affect the response to tyramine. These results suggest that norepinephrine when released from sympathetic nerve endings can activate prejunctional inhibitory beta 1-adrenoceptors to depress cholinergic neurotransmission in the bronchial wall.     

Ultrastructure of the basiepithelial nerve plexus of the sea urchin,Centrostephanus longispinus

Summary In submandibular glands of rabbits both adrenergic and cholinergic axons are intimately associated with parenchymal cells of the intercalary ducts and the granular tubules, lying beneath the basement membrane and often in the space between the parenchymal cell and an associated myoepithelial cell. The submandibular acini receive a less intimate and less plentiful innervation by adrenergic and cholinergic axons which remain outside the basement membrane and are still associated with Schwann cells. Occasional axons of both adrenergic and cholinergic type occur beneath the basement membrane of submandibular striated ducts in intimate association with basal parts of the cells.In the parotid glands numerous adrenergic and cholinergic axons are found beneath the basement membrane of acini and intercalary ducts in intimate association with the cells.This work has been helped by the technical assistance of Mr. P.S.A. Rowley     

Possible axo-axonal synapses between peripheral adrenergic and cholinergic nerve terminals

Summary The relations between adrenergic and cholinergic terminals were studied in rat iris and rat heart with the electron microscope. Adrenergic terminals were identified by treating the animals with 5-hydroxydopamine, which produces dense-cored synaptic vesicles in adrenergic terminals in tissues fixed in glutaraldehyde and osmium. The specificity of this observation was verified. It was found that adrenergic and cholinergic nerve terminals often come in close contact with one another, the distance between the adjoining membranes being about 250 Å. At times, faint membrane thickenings could be observed in these places. The available pharmacological, physiological, and morphological evidence leaves little room for doubt that cholinergic terminal fibres can influence the adrenergic fibres. From mainly morphological evidence, it is also postulated that adrenergic terminals influence cholinergic ones.This work was supported by grants from the United States Public Health Service (06701-04), the Faculty of Medicine, University of Lund, Lund, Sweden and the Swedish Medical Research Council (B70-14X-2321-03 and B70-14X-712-05). Svenska sällskapet för medicinsk forskning.     

Increase in the cholinergic cardiac plexus in sympathetically aneural chick hearts

Summary Embryonic chick hearts were made sympathetically aneural by removal of premigratory neural crest over somites 10–20. The cholinergic cardiac plexus was assessed at 12 to 15 days of incubation using morphological and biochemical techniques. The cholinergic innervation to the heart was increased by 50 to 100% due to both hypertrophy and hyperplasia of the ganglion cells as well as their terminals. The additional cells were an expansion of the normal population of cholinergic neurons in the heart rather than from some extra source. The expanded population of neurons did not express an adrenergic phenotype in response to the absence of adrenergic cardiac innervation.     

Electron microscopic investigation of adrenergic and non-adrenergic axons in the rabbit SA-node

Summary The rabbit SA-node was outlined electrophysiologically and its adrenergic and cholinergic innervation patterns were studied with the electron microscope. Differentiation between adrenergic and cholinergic terminals was achieved by fixation of the specimens in KMnO₄ which produces dense-cored synaptic vesicles in adrenergic terminals, whereas synaptic vesicles in cholinergic terminals are empty. It was found that adrenergic and cholinergic nerve terminals often come in close apposition to each other, the distance between adjoining membranes being in the order of 250 Å. At times, faint membrane thickenings could be seen in these places. The available pharmacological, physiological and morphological evidence leaves little room for doubt that cholinergic terminal fibers can influence the adrenergic ones. From mainly morphological evidence it is also postulated that adrenergic terminals influence cholinergic terminals.This work was supported by grants from Åhlén-Stiftelsen, the Faculty of Medicine, University of Lund, Lund, Sweden, the United States Public Health Service (project 06701-04) and the Swedish Medical Research Council (B70-14X-2321-03 and B70-14X-712-05).     

Dual innervation of arteries and arterioles

Summary Specific histochemical techniques for the demonstration of acetylcholinesterase and of norepinephrine have been used to study the distribution of cholinergic and adrenergic nerve fibers to arteries and arterioles in various organs of cats and dogs, including the male genital apparatus, tongue, skeletal muscle, heart and gastrointestinal tract. Arteries and arterioles in all of these organs showed both cholinergic and adrenergic nerve fibers, although the relative number of each of the types of fiber was variable. The findings provide morphologic evidence for a widespread and generalized dual adrenergic and cholinergic innervation of arteries and arterioles.Supported in part by Grant No. HE 10465 from the USPHS and by a grant from the Monroe County Heart Chapter.     

Cholinergic mechanisms in pial vessels

Summary Plexuses of cholinergic nerve terminals were demonstrated (acetylcholinesterase staining) in pial arteries (down to a diameter of about 15) at the base of the brain and on the brain convexities of mice, rats, rabbits, hamsters, guinea-pigs, and cats. The pial veins were less well supplied than the arteries. Consecutive formaldehyde gas treatment (to visualize adrenergic nerves) and acetylcholinesterase staining revealed that the adrenergic and cholinergic plexuses followed each other closely, the axon terminals running together in the same Schwann cell strands. This was confirmed by electron microscopy after KMnO₄ fixation or 5-hydroxydopamine treatment. The varicosities of cholinergic and adrenergic axons were sometimes seen as close as 250 Å. In the neuro-effector area, the terminals of both nerve types (naked or surrounded by an incomplete Schwann cell covering) approached the smooth muscle cells as close as 800–1100 Å, and they were separated from the latter only by the fused neuronal and muscular basement membranes. In this area axo-axonal contacts were observed. The adrenergic, but not the cholinergic, nerves disappeared after bilateral removal of the superior cervical sympathetic ganglia. Isolated cat middle cerebral artery contracted strongly with acetylcholine, and the effect was inhibited by atropine.With regard to the cholinergic neural control of the intracranial arteries, it may have particular functional implications: (1) that these vessels do have a cholinergic parasympathetic innervation in contrast to most other vascular systems, for example, in the mesenterium, (2) that this cholinergic nerve supply was found to be about equally prominent as the adrenergic (sympathetic) innervation which, in some pial vessels, is even better developed than in the mesenteric arteries, and (3) that the adrenergic and cholinergic systems in the intracranial arteries may interact, even at the level of the neuro-muscular contacts, a complex situation which may be partly responsible for the previous difficulties in defining the autonomic neural influence on the brain circulation.Part of the findings were reported at Journées Internationales de Circulation Cérébrale, Toulouse, April 21–22, 1972.     

Decentralisation of neurones in the pelvic ganglion of the guinea-pig: Reinnervation by adrenergic nerves

An electron-microscopic study has been made of adrenergic and cholinergic nerve fibres and synapses in the pelvic ganglion of the guinea-pig at intervals of up to 60 days following section of the hypogastric and pelvic nerves. Transection of the hypogastric nerves led to degeneration of 80-90% of the cholinergic nerve profiles and synapses in the ganglion. The small number of adrenergic nerves and synapses did not change, but 30-60 days after section, this number increased 8-10 times. Transection of the pelvic nerves led to degeneration of about 15% of the cholinergic nerve terminals, but no change in adrenergic terminals. After transection of both hypogastric and pelvic nerves, only about 1% of cholinergic nerves survived, but after 30-60 days, the number of adrenergic nerves increased 8-10 times. It is concluded that following cholinergic nerve degeneration in the ganglion, adrenergic nerves, probably originating as collateral sprouts from postganglionic neurones and granule-containing cells, can replace them to some extent.     

Innervation of iridic melanophores

Summary The nerve supply to the iridic melanophores of the rat was studied with the electron microscope. The adrenergic and cholinergic terminals were identified with the aid of 5-hydroxydopamine, which produces dense-cored 400–800 Å synaptic vesicles in adrenergic axon varicosities, whereas the synaptic vesicles of cholinergic axons remain empty. It was found that both adrenergic and cholinergic terminal axons come in close apposition (200–250 Å) with the melanophores. The appositions have the same appearance as synapses in peripheral tissues. It seems likely that the murine iridic melanophores have a double innervation, although its functional significance is obscure.This work has been supported by grants from Lunds Läkarsällskap, the Swedish Medical Research Council (Project no. B69-14X-2321-02 and B69-14X-712-04C) and NIH (06701-02).     

Studies on the acetylcholinesterase (ache)-positive and -negative autonomic axons supplying smooth muscle in the normal and 6-hydroxydopamine (6-OHDA)treated rat iris

Summary The adrenergic and cholinergic innervation to the rat iris has been studied at a light and electron microscopic level. Catecholamine fluorescence histochemistry showed adrenergic nerves to be present in both the dilatator and the constrictor pupillae regions. At a fine structural level the terminal innervation of the iris was studied and criteria for the differentiation between presumptive adrenergic and presumptive cholinergic axon terminals were examined. To aid this examination presumptive adrenergic axons were either labelled with the false adrenergic transmitter, 5-hydroxydopamine, or chemical sympathectomy performed using 6-hydroxydopamine. The value of using acetylcholinesterase staining as a marker for cholinergic nerve terminals was also studied.Results showed a mixed adrenergic/cholinergic innervation to the dilatator pupillae. In the constrictor pupillae an exclusively cholinergic innervation was found although adrenergic and cholinergic nerves were found supplying the blood vessels and at the dilatator-constrictor interface. These findings are discussed with regard to innervation-function relationships in the iris.     

The interrelations of the lymphatic capillaries with the nerve structures in the wall of the small intestine]

The character of interrelations of nervous structures and the lymphatic capillary walls has been studied in cats. Under the light microscope twisted nervous fiber terminals of the intestinal neuron dendrites have been revealed around the lymphatic capillaries. Electron microscopical investigation has not revealed any specialized contacts of the nervous terminals and the lymphatic capillary walls. The receptors and terminals of axons do not situate nearer than 10 nm from the latter. According to the structure of synaptic vesicles among the axonal terminals next to the lymphatic capillary walls cholinergic, adrenergic and purinergic ones are described. The influence of the nervous system to the function of the small intestine lymphatic capillaries is mediated via the precapillary space. The neuromediators from the axonal terminals get into it owing to absence of neurolemmocytic membranes around them.     

Ultrastructure of the corneal nerves in the Rat

Summary The ultrastructure of the corneal nerves of the rat was studied in tissue fixed by immersion in and by perfusion with glutaraldehyde-containing fixatives. Of the four types of axonal terminal identified in the nerves, those with the features of adrenergic and cholinergic terminals were confined to the nerves at the limbus and were concentrated in the perivascular plexuses. The remaining two types of terminal were found on axons located in all parts of the cornea and on both intraepithelial axons and axons in the stromal nerves. Of these, one contained the numerous mitochondria which occur in the terminals of axons associated with known mechanoreceptors and the second contained variable and often small numbers of both clear and large dense-cored vesicles. While most of the mitochondria-containing terminals were seen in nerves located near the periphery, vesicle-containing terminals were numerous in all of the nerves, and especially in those in the avascular cornea. In material fixed by immersion in glutaraldehyde-paraformaldehyde, the vesicle-containing terminals appeared to be dilated, but in material fixed by perfusion there was little evidence of any increase in the diameter of the axons in the terminal regions. The structure of the terminals was compared with that of the terminals of axons identified in the nerves of the skin and the urinary tract and the differences in the vesicle content of the terminals to those reported in other studies of the corneal nerves was related to the use of different fixation procedures. The possibility that axons possessing such terminals are identical with the beaded axons and both the cholinesterase-positive and fluorescent axons demonstrated in light microscopical studies of the corneal nerves is discussed, and the widespread distribution of the axons in the cornea is equated with the hypothesis that they are afferent in nature and represent the peripheral receptors for pain impulses.     

Membrane properties of cultured rat sympathetic neurons: Morphological studies of adrenergic and cholinergic differentiation

Dissociated neurons from the newborn rat superior cervical ganglion were grown under conditions which lead to either adrenergic or cholinergic differentiation. Lectins and toxins were used to detect differences in the cell membrane associated with transmitter status, age of the neurons, or location on the neurons. These ligands were made visible in the light or electron microscope by coupling to rhodamine or colloidal gold. The density of binding sites for concanavalin A (Con A), ricin (RCA₆₀), and wheat germ agglutinin (WGA) increased with age in culture on both adrenergic and cholinergic cells. Soybean agglutinin (SBA) binding increased about threefold on adrenergic axons, but failed to increase on neurons induced to become cholinergic by medium conditioned by rat heart cells (CM). The effect of CM on SBA binding paralleled previously described effects of CM on transmitter production; the CM binding pattern developed slowly and was not readily reversible. Mature adrenergic neurons also appeared to bind more WGA than neurons in CM cultures. Tetanus toxin gold binding was uniform, but low, on axons of adrenergic and cholinergic neurons at all ages. In contrast, cholera toxin binding decreased with age on adrenergic axons. Binding sites for SBA and tetanus toxin were found to be less numerous on the cell body surface than on the axonal surface. Thus growth in CM induces fundamental changes in the phenotype of developing sympathetic neurons involving the cell membrane as well as transmitter choice. Differences also appear with maturation and between axonal and somatic cell surface membranes.     

Development of adrenergic neurons in uiuo: inhibition by ganglionic blockade

T he N ormal biochemical maturation of postsynaptic adrenergic neurons in mouse and rat superior cervical ganglion depends upon an intact preganglionic innervation (B lack , H endry and I versen , 1971a, 1972; T hoenen , S aner and K eitler , 1972). In recent studies tyrosine hydroxylase, the rate-limiting enzyme in norepinephrine biosynthesis (L evitt , S pector , S joerdsma and U denfriend , 1965), with localization to adrenergic neurons in the ganglion (B lack , H endry and I versen , 1971b), was used to monitor maturation of these cells. The developmental increase in tyrosine hydroxylase activity occurred simultaneously with the appearance of ganglionic synapses and was prevented by transection of the preganglionic nerve trunk (B lack , H endry and I versen , 1971a). These observations suggest that presynaptic cholinergic nerve terminals regulate the biochemical development of postsynaptic neurons in the superior cervical ganglion. The mechanism(s) by which presynaptic cholinergic terminals regulate postsynaptic development has not been elucidated. Such trans-synaptic regulation may be dependent on normal impulse transmission and/or may involve other unidentified, trophic factors. The results presented in the present communication suggest that normal development of ganglionic tyrosine hydroxylase activity is dependent on depolarization of postsynaptic adrenergic neurons.