Interactions between autonomic nerves and smooth and cardiac muscle cells in tissue culture

Specific interactions occur between nerve fibers from cultured sympathetic ganglia of guinea pigs and rats and single muscle cells from vas deferens and heart. The associations are long-lasting and resemble the pattern of autonomic neuromuscular relations in situ. In contrast, any associations formed between sympathetic nerve fibers and fibroblasts appear to be temporary. The results are discussed in relation to the normal innervation of smooth muscle and the reinnervation of explants.     

Trophic influences of sympathetic nerves and cyclic AMP on differentiation and proliferation of isolated smooth muscle cells in culture

Smooth muscle cells of the newborn guinea-pig vas deferens dispersed into single cells and grown in culture maintain their differentiation for approximately 5 days before undergoing dedifferentiation and mitosis. The presence of sympathetic nerve fibres in contact with the isolated cells delays this process by 3-7 days (Chamley et al., 1974). A similar delay in dedifferentiation of vas deferens smooth muscle cells in tissue culture in the presence of sympathetic ganglion extract is described in the present report, demonstrating that the trophic effect is elicited by a chemical substance. This effect is mimicked by the presence of either a confluent layer of RKA epithelial cells, dibutyryl cyclic AMP or theophylline. A similar, but considerably weaker, effect is also obtained with spinal cord and liver extracts and noradrenaline. Acetylcholine does not show an effect. It is suggested that a trophic substance (probably not noradrenaline) from sympathetic neurons activates the adenyl cyclase system of smooth muscle cells to increase the intracellular level of cyclic AMP which in turn promotes and maintains the differentiation of the cultured smooth muscle cells.     

Three-dimensional arrangement of muscle bundles in the outer layers of rodentia vasa deferentia

Three-dimensional arrangement of the smooth muscle bundles of the outer layer of the vas deferens musculature in mammals (guinea-pigs, rats and mice) was examined under the scanning electron microscope (SEM) after removal of fibrous connective tissue elements. Muscle fibers of all examined animals formed bundles. In the guinea-pig, similar sized bundles extended longitudinally along the tubular vas deferens and branched to anastomose with branches of neighboring bundles to create a net which was regular in form. In the rat, longitudinal muscle bundles constituted an outer layer in the form of a net, which was roughly enmeshed with variously-sized, transverse or oblique bundles in anastomosis with underlying longitudinal bundles. In the mouse, longitudinal bundles of irregular thickness branched into many small bundles and anastomosed not only with neighboring bundles to create an irregular net. In both the rat and the mouse there were bundles extending over many other bundles to anastomose with them at a far point. Junctional structures were well developed between neighboring fibers. Myofibrils were represented as thin streaks on muscle fiber surfaces. Varicosed nerve fibers existed between muscle fibers and in narrow cytoplasmic grooves in all the examined animal species. The findings are discussed in correlation with electrophysiological data.     

The nervous environment of individual smooth muscle cells of the guinea pig vas deferens

Smooth muscle cells of the external longitudinal coat of the guinea pig vas deferens were followed for 480 mu at 4.5-mu intervals. Muscle bundles and fibers interwove, facilitating intermuscular and neuromuscular contacts. The ribbon- or rodlike muscle cells were about 450 mu long, 3,000 mu3 in volume, and 4,500 mu2 in area. The thickened nuclear zone day anywhere along the middle one-third of the cell. Intercellular distances were 500-800 A. Intrusions were rare, and tight-junctions absent. At any level in a field of 80 muscle fibers there were 10-15 nerve bundles, each containing several varicose axons. Bundles and axons divided. Axons, en passage, were frequently within 500-1,000 A of a muscle fiber. En passage close contacts were rate. Axon terminations were bare, and bare axons invariably terminated. Bare terminations had scattered vesicle-laden varicosities and were from 10-60 mu in length, and all ended within 500 A of muscle fibers. Some made close contact with muscle fibers. Less than half of the muscle cells received this close contact, but some cells were approached by more than one termination. Most terminations involved more than one cell. Some cells had little or no innervation. Some groups of cells had a rich innervation. There was very little evidence of sensory innervation. These conclusions are not valid for other smooth muscles.     

Effect of ten different target tissues on nerve fibre outgrowth from rat sympathetic ganglia in organotypic co-cultures

Sympathetic thoracic chain ganglia of 3-day-old rats were cultured in collagen gel medium for 24 hours together with explants from heart atrium, liver, kidney, cornea, iris, lung, adrenal cortex, adrenal medulla, skeletal muscle, or vas deferens. The extent of nerve fibre growth was estimated by counting the number of fibres crossing each arc of a sector drawn in the ocular. The various tissues stimulated nerve fibre growth to distinctly different extents. The increase in the nerve fibre outgrowth induced by atrium and iris was statistically highly significant. Kidney, liver, vas deferens, lung, and adrenal cortex had, in that order, a decreasingly stimulatory influence on sympathetic chain ganglia. Yet they all caused a significant increase in nerve fibre growth. Skeletal muscle, cornea and adrenal medulla had no stimulatory effect. Since the significant effects of the tissue explants were abolished by antiserum to nerve growth factor (NGF), it is concluded that the observed effects were due to NGF produced by the explants. The only exception was vas deferens, the stimulatory action of which proved to be partially NGF-independent.     

Coexistence and cooperation between neuropeptide Y and norepinephrine in nerve fibers of guinea pig vas deferens and seminal vesicle

Fluorescence immunocytochemistry of guinea pig vas deferens and seminal vesicle revealed dense networks of nerve fibers containing both neuropeptide Y (NPY) and dopamine-beta-hydroxylase (DBH), a marker for adrenergic neurons. The effects of norepinephrine (NE) and NPY on the smooth musculature of these organs were studied in vitro. NE inhibited the response to electrical nerve stimulation and increased the basic tension in the vas deferens and contracted the smooth muscle of the seminal vesicle, but had no effect on the contractile response to transmural stimulation in the latter organ. NPY had similar effects on the vas and vesicula, i.e. it inhibited the electrically induced contractions and had no effect on the basic tension. The results suggest a role for NPY as a transmitter that acts before the site of the neuromuscular junction to modulate the release of other transmitters from motor nerve fibers in the smooth musculature.     

Enkephalin-immunoreactive nerve fibers in the feline genito-urinary tract

Summary Besides the classical neurotransmitters acetylcholine and norepinephrine the genito-urinary tract contains also neuropeptides. The distribution of substance P- and VIP-containing nerve fibers have earlier been described. Also enkephalin-immunoreactive nerve fibers occur in the male and female genito-urinary organs of the cat. The nerves are more numerous in male than in female genital tract. The prostatic gland and vas deferens receive the largest supply. In the female genital tract the enkephalin-immuno-reactive nerve fibers are regularly seen in the smooth muscle layer of the cervix. Of special interest is the rich occurrence of the enkephalin nerve fibers among the nerve cell bodies in the para-urethral and cervical ganglia supporting the view that enkephalin may play a neuromodulating role.     

Action of morphine on guinea-pig myenteric plexus and mouse vas deferens studied by intracellular recording.

Morphine reduces the output of transmitter from the myenteric plexus-longitudinal muscle preparation of the guinea-pig ileum and from the mouse vas deferens. Intracellular recordings were made from ganglion cells of the myenteric plexus and smooth muscle cells of the vas deferens. Synaptic transmission within the myenteric plexus was blocked by hexamethonium. Morphine did not change the properties of the ganglion cells, nor did it affect synaptic potentials. 5-Hydroxytryptamine inhibited acetylcholine release at intraganglionic synapses by an action which was unaffected by morphine. In the vas deferens, excitatory junction potentials were elicited by stimulation of postganglionic adrenergic nerve fibres. The junction potentials were depressed by morphine and levorphanol but not by dextrorphan. This depression was reversed by naloxone. The results indicate that morphine acts directly to reduce transmitter release at the neuro-effector junctions in the myenteric plexus-longitudinal muscle preparation and in the vas deferens in these species.     

Breeding and post-breeding structure of the vas deferens of the long-toed salamander Ambystoma macrodactylum

The vas deferens of Ambystoma macrodactylum is composed of a peritoneal epithelium, connective tissue layer with fibroblasts, circular smooth muscle, capillaries, cells containing lipid, and a luminal epithelium composed of a single layer of cuboidal cells covered by a net of interconnected ciliated squamous cells. The cuboidal cells have abundant rough endoplasmic reticulum, mitochondria, and PAS + secretory vesicles. Squamous cells of breeding males consistently have tufts of ～100 cilia located at one end of the long axis of each cell. These cilia may help distribute secretory products. The squamous cells, absent in post-breeding males, are apparently sloughed into the lumen. Lipid vesicles are present throughout the cytoplasm of the cuboidal and squamous epithelial cells and are also in some cells of the connective tissue layer. These vesicles increase dramatically in number during the first 4 weeks after breeding and may serve as an energy pool for the next breeding season. Enzyme-histochemical tests for testosterone synthesis were negative. In addition to the accumulation of lipid and the loss of squamous cells in the vas deferens, after breeding PAS + vesicle production is terminated. These alterations appear to represent energy conservation strategies employed by the sperm-depleted vas deferens.     

The long-term influence of decentralisation or preganglionic hypogastric nerve stimulation in vivo on the reinnervation of minced vas deferens in the guinea-pig

Previous studies have shown that minced regenerating smooth muscle of the guinea-pig vas deferens becomes reinnervated by nerves growing in from the surrounding intact vas deferens. Using electron microscopy, we have examined the effect of altering activity in the preganglionic nerves, either by decentralisation, or by chronic stimulation of the hypogastric nerve, in vivo, on the reinnervation of regenerating smooth muscle cells. Chronic stimulation induced earlier reinnervation than that seen in unstimulated (sham-operated) or decentralised preparations; the number of nerve profiles present in four preparations stimulated for up to 7 days was approximately 10-20 times that seen in unstimulated or decentralised preparations. However, electron micrographs revealed that "empty" nerve terminals were a feature following stimulation for longer periods. Decentralised preparations showed little change of reinnervation, at least up to 7 weeks. Compensatory changes in the density of innervation were found in the unstimulated contralateral vas deferens.     

Specificity of nerve fibre 'attraction' to autonomic effector organs in tissue culture.

Explants of atrium, vas deferens and lung from 5-day-old rats were grown between, and 1–2 mm from, a row each of sympathetic ganglia and spinal cord explants. After 5 days the amount of sympathetic nerve fibre growth in cultures with atrium or vas deferens (but not lung) was greater than in controls and directed towards the tissues. In contrast, in cultures with atrium, vas deferens and lung, the direction and amount of nerve growth from spinal cord explants was not significantly different from controls. Further, when sympathetic ganglia were grown between, and 1–2 mm from, a row each of atrium and ventricle explants, the total amount of nerve growth was increased and directed mainly towards the atrium. The results are discussed in relation to the hypothesis that normally densely innervated autonomic effector organs contain higher levels of Nerve Growth Factor than tissues which become more sparsely innervated, and that this allows nerve fibres from sympathetic ganglia (but not NGF-insensitive spinal cord) to distinguish between different tissues from a distance.     

Altered mechanical properties in smooth muscle of mice with a mutated calponin locus

The mechanical properties of smooth muscles in aorta and vas deferens were studied in mice with a mutated basic calponin locus to learn the physiological function of calponin. The intact smooth muscles were stimulated with high KCl and the force development was compared between calponin deficient (knockout, KO) mice and wild type (WT) ones. The isometric force induced by various concentrations of high KCl was lower in KO than in WT both in aorta and in vas deferens. The length-force relations were compared between KO and WT. The active isometric force in KO was significantly lower at most muscle lengths examined than in WT without the change in resting force both in aorta and in vas deferens. In vas deferens, the rate of force development after quick release in length at the peak force was significantly faster in KO than in WT. The above results show that the force development is lower and the rate of cross-bridge cycle is faster in KO mice than in WT ones, suggesting that calponin plays basic roles in the control of the contraction of smooth muscle.     

Sympathetic innervation of the reproductive organs of the male opossum, Didelphis albiventris (Lund, 1841)

The dissection of nerves and ganglia anatomically related to the pelvic organs revealed one inferior mesenteric ganglion, two testicular ganglia, two hypogastric nerves, two pelvic ganglia and two pelvic nerves. The histochemical demonstration of catecholamines by a glyoxylic acid fluorescence method revealed a rich sympathetic innervation in the ductus deferens, in the three segments of the prostate and in the convoluted ductuli efferentes. The testis, epididymis and all three pairs of bulbourethral glands presented fluorescent nerve fibers only around blood vessels. Removal of the inferior mesenteric and testicular ganglia, and hypogastric neurectomy with our without ligature and sectioning of testicular arteries, had no effect on the density of the nonvascular fluorescent fibers. Removal of the periprostatic tissue caused complete denervation of the prostate and marked denervation of the ductuli efferentes and ductus deferens. Small ganglia containing fluorescent nerve cell bodies were found close to the capsule of the prostate. The results indicate that short adrenergic neurons are responsible for the sympathetic innervation of the reproductive organs of the male opossum.     

Effect of calcitonin gene-related peptide on the neuroeffector mechanism of sympathetic nerve terminals in rat vas deferens

In order to evaluate the mode of action of calcitonin gene-related peptide (CGRP) on the neuroeffector mechanism of peripheral sympathetic nerve fibers, the effects of CGRP were tested on the electrical stimulated and the non-stimulated preparations of the isolated rat vas deferens. The contractile responses, which were mediated predominantly by activation of postganglionic noradrenergic nerve fibers, were dose-dependently inhibited by CGRP in concentrations ranging from 0.1 to 10 nM. The inhibitory response produced by CGRP in high concentrations (greater than 2 nM) usually returned to the control level at 20-30 min and were rarely tachyphylactic. The inhibitory action of CGRP was not modified by pretreatment with 10(-7) M propranolol or 10(-7) M atropine. Contractions produced by exogenous norepinephrine (NE) and 5-hydroxytryptamine (5-HT) in unstimulated preparations were not affected by pretreatment with CGRP in a low concentration (less than 2 nM). On the other hand, the contractions were slightly reduced 1 min after pretreatment with CGRP in high concentrations (greater than 5 nM), which recovered in 15 min after constant flow washout. High concentrations of CGRP also caused a concentration-dependent relaxation on the precontracted preparations produced by high potassium (60 mM K+) solution. These results suggest that CGRP in high concentrations (greater than 5 nM) may have a non-specific inhibitory action on the postsynaptic plasma membrane of the smooth muscle cell and a postulated CGRP receptor exists presynaptically in the rat vas deferens and that CGRP may inhibit the release of NE during adrenergic nerve stimulation.     

Innervation of the guinea pig spleen studied by electron microscopy

The innervation of the guinea pig spleen was investigated by electron microscopy. Unmyelinated nerve fibers in the capsulotrabecular and arterial systems were found to contain large and small granular and small agranular synaptic vesicles in their terminals and are thought to be sympathetic adrenergic in nature. They influence the contraction of the smooth muscle cells by diffusion innervation in these systems. These nerve terminals were also scattered in both the red and the white pulp. Pulp nerves wrapped by Schwann cells were further enclosed by myofibroblastic reticular cells. This condition revealed that the pulp nerves pass through the connective-tissue spaces of the reticular fibers, which contain elastic fibers, collagenous fibrils, and lamina densa-like materials of the usual basement laminae. One of the target cells for the pulp nerves is considered to be the myofibroblastic reticular cell in the reticular meshwork. Neurotransmitter substances released from the naked adrenergic nerve terminals travel through the reticular fibers and may play a role, by both close association innervation and diffusion innervation, in the contraction of reticular cells to expose the reticular fibers. At the exposed sides, connective-tissue elements of the reticular fibers are bathed with blood plasma, and the included naked nerve terminals, devoid of Schwann cells but with basement laminae of these cells, face free cells at some distance or are in close association with free cells, especially lymphocytes, macrophages, and plasma cells. The close ultrastructural relationship between the naked adrenergic nerve terminals and immunocytes strongly suggests that there is an intimate relationship between the immune system and the sympathetic nervous system through both close association innervation and diffusion innervation. Thus splenic adrenergic nerves of the guinea pig may play a triple role in 1) contraction of smooth muscle cells to regulate blood flow in the organ, 2) induction of the exposure of reticular fibers by contraction of the reticular cells in order to form a close relationship of the nerve terminals with the immunocytes, and 3) subsequent neuroimmunomodulation of the immunocytes.     

COMPARISON OF SPONTANEOUS LOSS OF CATECHOLAMINES AND ATP IN VITRO FROM ISOLATED BOVINE ADRENOMEDULLARY, VESICULAR GLAND, VAS DEFERENS AND SPLENIC NERVE GRANULES

The molar ratio catecholamines/ATP in the high speed sediment from homogenates of bovine adrenal medulla, vesicular gland, vas deferens and splenic nerve was relatively close to the‘equivalence ratio’of 4/1. On incubation in vitro the loss of amines and ATP from the medullary granules was slow and largely parallel. Thus the original amine/ATP ratio was maintained. The amine loss from the nerve granules occurred at a very high, and from the vesicular gland and vas deferens granules at an intermediate, rate. On the other hand, the decrease in ATP in these preparations was quite slow, leading to a marked change in the original amine/ATP ratio. These findings are regarded as further evidence of functional differences between granules derived from chromaffin cells and from sympathetic nerve tissue, and even between nerve granules from‘long’and 'short’noradrenergic neurons. The possible implications of these in vitro differences in amine and ATP release are discussed in relation to the mechanisms of amine release in vivo.     

Organization of the sympathetic innervation in liver tissue from monkey and man

Summary The sympathetic innervation of the liver of monkey and man has been investigated in a combined fluorescence histochemical, chemical and electron microscopical study. By means of the Falck-Hillarp fluorescence method a dense network of monoamine-containing nerve fibers was visualized in liver tissue of monkey and man. The nerve fibers ran in close contact to both hepatocytes and blood vessels. Chemical quantitations showed high concentrations of noradrenaline in both human and monkey liver. Microspectrofluorometry of the intraneuronal monoamine resulted in spectra characteristic of a catecholamine. For the electron microscopical study the dopamine analogue, 5-hydroxydopamine, was used to label the catecholamine terminals in both human and monkey liver. The nerve profiles, identified as catecholamine-containing, were demonstrated in a perivascular location and in close contact to hepatocytes. No synaptic membrane specializations were present between nerve fibers and hepatocytes. The general ultramorphology and intralobular distribution pattern of nerves in the liver of monkey and man were similar. The present results prove the existence of a sympathetic innervation of hepatocytes and blood vessels in the liver of man and monkey.     

Differential Effects of Chemical Sympathectomy on Expression and Activity of Tyrosine Hydroxylase and Levels of Catecholamines and DOPA in Peripheral Tissues of Rats

Tyrosine hydroxylase (TH) mRNA and activity and concentrations of 3,4-dihydroxyphenylalanine (DOPA) and catecholamines were examined as markers of sympathetic innervation and catecholamine synthesis in peripheral tissues of sympathectomized and intact rats. Chemical sympathectomy with 6-hydroxydopamine (6-OHDA) markedly decreased norepinephrine and to a generally lesser extent TH activities and dopamine in most peripheral tissues (stomach, lung, testis, duodenum, pancreas, salivary gland, spleen, heart, kidney, thymus). Superior cervical ganglia, adrenals and descending aorta were unaffected and vas deferens showed a large 92% decrease in norepinephrine, but only a small 38% decrease in TH activity after 6-OHDA. Presence of chromaffin cells or neuronal cell bodies in these latter tissues, indicated by consistent expression of TH mRNA, explained the relative resistance of these tissues to 6-OHDA. Stomach also showed consistent expression of TH mRNA before, but not after 6-OHDA, suggesting that catecholamine synthesizing cells in gastric tissue are sensitive to the toxic effects of 6-OHDA. Tissue concentrations of DOPA were mainly unaffected by 6-OHDA, indicating that much of the DOPA in peripheral tissues is synthesized independently of local TH or sympathetic innervation. The differential effects of chemical sympathectomy on tissue catecholamines, DOPA, TH mRNA and TH activity demonstrate that these variables are not simple markers of sympathetic innervation or catecholamine synthesis. Other factors, including presence of neuronal cell bodies, parenchymal chromaffin cells, non-neuronal sites of catecholamine synthesis and alternative sources of tissue DOPA, must also be considered when tissue catecholamines, DOPA and TH are examined as markers of sympathetic innervation and local catecholamine synthesis.     

Morphological and biochemical changes in supersensitive smooth muscle.

The effect of postganglionic denervation on the incidence of nexal contacts in the smooth muscle of the rat vas deferens was investigated. The chronically denervated tissue exhibited twice as many nexuses as control. This increase in the incidence of cell contacts may contribute to the supersensitivity and/or the increase in maximum response of the denervated vas deferens. The effects of denervation, decentralization, and pretreatment with reserpine on the concentration of adenosine triphosphate (ATP) in vasa deferentia of rats and guinea pigs were also investigated. One day after denervation there was a substantial decrease in the endogenous norepinephrine and ATP concentrations. The norepinephrine concentration remained low (less than 10% of control) throughout subsequent days (up to 14 days) whereas the ATP concentration, after the first postoperative day, rose significantly. The rise in ATP concentration was temporally correlated with the development of postjunctional supersensitivity. Decentralization and pretreatment with reserpine both resulted in a significant increase in ATP concentration which preceded by 2 to 3 days a significant increase in sensitivity of the vas deferens. It appears that a change in the tissue concentration of ATP may be one of the initial events that occurs following interruption of the neural contact to the smooth muscle of the vas deferens.     

Immunocytochemical demonstration of dopamine-beta-hydroxylase and cytochrome B561 on the axonal reticulum in bovine sympathetic neurons.

In sympathetic neurons the axonal reticulum can be considered an extension of the secretory pole of the Golgi apparatus. If this tubular system indeed represents the neurosecretory apparatus, it would likely contain on its membranes the enzymes involved in catecholamine synthesis. To test this hypothesis, we investigated the distribution of dopamine-beta-hydroxylase and cytochrome b561 in bovine splenic nerve and nerve terminals in the vas deferens with an immunogold procedure after glycolmethacrylate embedding. Counterstaining with phosphotungstic acid at low pH selectively revealed the axonal reticulum elements. With antibodies against both enzymes, gold labeling was observed over the large dense-cored vesicles, the Golgi-associated axonal reticulum, the reticulum within axons, and the tubular complex at the nerve terminal. From our results it can be concluded that in sympathetic neurons the axonal reticulum represents a tubular neurosecretory system, extending from the Golgi apparatus in the cell soma to the nerve terminal. This concept emphasizes the local production of neurosecretory vesicles and may be of importance in the interpretation of neuronal transmission in normal and diseased states.