Histochemistry and ultrastructure of adrenergic and acetylcholinesterase-containing nerves supplying follicles and endocrine cells in the guinea-pig ovary

Summary With the use of an anti-human S-100 protein antibody, it was possible to reveal a characteristic cell type in the anterior lobe of the normal human pituitary. These cells, so-called folliculo-stellate cells, were present in all pituitaries studied but their number varied from one gland to another. Immunoreactive cells, isolated or grouped, were arranged close to various secretory granulated cells. Especially by use of double immunoenzymatic labeling, it was evident that these cells are spatially related either to somatotropes, prolactin cells and corticotropes, or to glycoprotein-containing cells. Such immunoreactive cells were rare or absent in pseudo-follicular arrangements of secretory granulated cells. Since it is now possible to identify this cell type by light microscopy and since no reliable functional significance is known, it seems more advisable to term this cell type stellate cell instead of folliculostellate cell.     

Neurogenic relaxation mediated by vasoactive intestinal polypeptide (VIP) in the isthmus of the human fallopian tube

The smooth musculature of the Fallopian tube is important for normal ovum transport, fertilization and implantation. Little is known about the factors controlling the motor activity of the isthmic sphincter. Studies were performed on smooth muscle preparations from the human tube in vitro. Electrical field stimulation of the nerves in the isthmic region reduced the motor activity, particularly in the circular muscle. The response was unaffected by adrenergic and cholinergic antagonists, but blocked by tetrodotoxin, suggesting a neural involvement. Vasoactive intestinal polypeptide (VIP) was considered a likely candidate for the neural mediation of this response in view of the high density of VIP-containing nerve fibres in this region, and in view of the fact that exogenous VIP causes a marked reduction of the tubal motor activity. To test whether VIP might be the endogenous mediator of this effect, nerve stimulation was carried out in the presence of large amounts of exogenous VIP in order to occupy all VIP receptors; the motor inhibitory action of VIP was counteracted by vasopressin. Under these conditions, nerve stimulation failed to reduce isthmic motor activity. This was not due to vasopressin since reduction occurred in the presence of this peptide alone. The results suggest that VIP is responsible for the neurogenic inhibition of motor activity in the isthmus region of the human Fallopian tube.     

Adrenergic and cholinesterase-containing neurons of the heart

Summary The adrenergic and acetylcholinesterase-containing nerves of the hearts of mice, rats, guinea-pigs, rabbits, and cats were studied. The fluorescence technique of Falck and Hillarp was used for the demonstration of adrenergic nerves, whereas a modified Koelle cholinesterase technique was used for the cholinesterase-containing nerves. The inhibitors used were Mipafox, iso-OMPA and Nu 683. Microspectrofluorometry was used to identify the structures containing dopamine.Adrenergic as well as acetylcholinesterase-containing fibres were found in all parts of the heart, most abundantly in the atria. Dense nerve plexa supplied the sinoarial and atrioventricular nodes. There was a plexus of both fibre types in the endocardium and on the atrial side of the valves. In the valves, it could be shown that adrenergic and cholinesterase-containing fibres ran closely parallel to each other. Indirect evidence suggested that this applies also to the myocardium.No nerve fibres containing dopamine were revealed in the microspectrofluorometer. The dopamine previously found in the atria seems, instead, to be situated in so-called small intensely fluorescent cells.No adrenergic ganglion cells were found in the heart despite extensive search. The vagus of rabbits was found to contain only few adrenergic preterminals.     

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).     

Comparative study of the autonomic innervation of the mammalian ovary,with particular regard to the follicular system

Summary The autonomic innervation of the ovary was studied in 12 mammalian species utilizing the cholinesterase method in combination with pseudocholinesterase inhibition for the cholinergic component, and glyoxylic acid histochemistry together with fluorometric determination of noradrenaline for the adrenergic component. Ovaries from cow, sheep, cat, and guinea pig were very richly supplied with adrenergic nerves in the cortical stroma, particularly enclosing follicles in various stages of development. In the follicular wall the nerve terminals were located in the theca externa, where they ran parallel to the follicular surface. Numerous adrenergic terminals also surrounded ovarian blood vessels. The adrenergic innervation was of intermediary density in the human ovary and in the pig, dog, cat, and opossum. Ovaries from rabbit, mouse and hamster had a sparse adrenergic nerve supply. The amount of intraovarian adrenergic nerves agreed well with the tissue concentration of noradrenaline in the various species. The cholinergic innervation was generally less well developed, but had the same distribution as the adrenergic system around blood vessels and in the ovarian stroma, including follicular walls.     

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.     

Electron microscopic identification of the histamine-storing argyrophil (enterochromaffin-like) cells in the rat stomach

Summary In the oxyntic gland area of the rat stomach the histamine-containing epithelial cells (also referred to as enterochromaffin-like cells because of their morphologic similarity with the 5-hydroxytryptamine-storing enterochromaffin cells) constitute the system of argyrophil cells in this area as previously shown by the combined use of fluorescence and light microscopic techniques. By performing the argyrophil staining reaction directly on ultra-thin sections it could be demonstrated in the electron microscope that the argyrophil cells have features suggesting that they are endocrine. Based on the ultrastructure of their secretory granules at least two such endocrine cell systems—both argyrophil—could be recognized in the oxyntic glands. The silver deposits were accumulated over the secretory granules of both these cell systems.It is well known that after injection of 1-3,4-dihydroxyphenylalanine, the histamine-storing (enterochromaffin-like) cells of the oxyntic glands store also dopamine. Under these conditions the enterochromaffin-like cells stain argentaffin, which has been shown at the light microscopic level. Also this reaction could be performed directly on ultra-thin sections. By electron microscopy it was then established that the two endocrine cell systems of the oxyntic gland area stained argentaffin upon treatment with 1-3,4-dihydroxyphenylalanine, and that the staining was confined to the secretory granules.The results clearly show that the enterochromaffin-like cells of the rat oxyntic gland area (which is devoid of 5-hydroxytryptamine-containing enterochromaffin cells) are identical with cells characterized as endocrine by ultrastructural criteria, and that gastric non-mast-cell histamine occurs in at least two separate systems of enterochromaffin-like cells.     

Simultaneous demonstration of adrenergic and non-adrenergic nerve fibres

Summary A technique for simultaneous demonstration of adrenergic and non-adrenergic nerve fibres is described, using methylene blue staining and fluorescence microscopy after formaldehyde treatment. The procedure is applicable to whole mounts as well as to microtome sections.