The ultrastructure of Auerbach's plexus in the guinea-pig. II. Non-neuronal elements

Summary The ultrastructural features of non-neuronal cells associated with Auerbach's plexus in the stomach, ileum and colon of the guinea-pig have been examined. Apart from Schwann, mast and interstitial or fibroblast-like cells, two other cell types are described that do not appear to have been reported previously. Of these two cell types, one was found external, but close to, the plexus and contained large granular vesicles. The other cell type contained numerous glycogen-like granules, was situated close to or within axon bundles and had processes that extended within and peripheral to nerve bundles as well as being close to smooth muscle cells. Although axon varicosities were opposed to both the processes and cell body of the second type of cell, synaptic-like contacts were not observed.     

Direct contacts between Auerbach's ganglia and smooth muscle cells in the small intestine of the rat

The present electron microscopic study demonstrated direct contacts between Auerbach's ganglia and longitudinal smooth muscle cells in the rat small intestine. The muscle cells were often observed to extend small, foot-like processes to the Auerbach's ganglia. These processes were in contact with glial cells in the ganglia without an intervening basal lamina, or were in contact with intraganglionic axon varicosities containing many synaptic vesicles. The processes in contact with glial cells may anchor the muscle cells to the ganglia during muscle contraction and those in contact with axon varicosities may function as synaptic sites between ganglion and longitudinal muscle cells.     

Specialised sympathetic neuroeffector associations in immature rat iris arterioles

Sympathetic nerve-mediated vasoconstriction in iris arterioles of mature rats occurs via the activation of α_1B-adrenoceptors alone, while in immature rat iris arterioles, vasoconstriction occurs via activation of both α₁- and α₂-adrenoceptors. In mature rats the vast majority of sympathetic varicosities form close neuroeffector junctions. Serial section electron microscopy of 14 d iris arterioles has been used to determine whether restriction in physiological receptor types with age may result from the establishment of these close neuroeffector junctions. Ninety varicosities which lay within 4 μm of arteriolar smooth muscle were followed for their entire length. Varicosities rarely contained dense cored vesicles even after treatment with 5-hydroxydopamine. 47% of varicosities formed close associations with muscle cells and 88% formed close associations with muscle cells or melanocytes. Varicosities in bundles were as likely as single varicosities to form close associations with vascular smooth muscle cells, although the distribution of synaptic vesicles in single varicosities did not show the asymmetric accumulation towards the smooth muscle cells seen in the varicosities in bundles which were frequently clustered together. We conclude that restriction of physiological receptor types during development does not appear to correlate with the establishment of close neuroeffector junctions, although changes in presynaptic structures may contribute to the refinement of postsynaptic responses.     

Schwann cell dynamics with respect to newly formed motor-nerve terminal branches on mature (Bufo marinus) muscle fibers

A study has been made of the formation of synaptic terminals from long processes formed at the end of motor nerve branches of endplates in mature amphibian (Bufo marinus) muscle. Injection of fluorescent dyes into individual motor axons showed the full extent of their branches at single endplates. Synaptic vesicle clusters at these branches were identified with styryl dyes. Some terminal branches consisted of well separated varicosities, each possessing a cluster of functioning synaptic vesicles whilst others formed by the same axon consisted of closely spaced clusters of vesicles in a branch of approximately uniform diameter. All the varicosities gave rise to calcium transients on stimulation of their parent axon. Both types of branches sometimes possessed short processes (<5 microm long) or very long thin processes (>10 microm long) which ended in a bulb that possessed a functional synaptic vesicle cluster. These thin processes could move and form a varicosity along their length in less than 30 min.Injection of a fluorescent dye into terminal Schwann cells (TSCs) at an endplate showed that they also possessed very long thin processes (>10 microm long) which could move over relatively short times (<30 min). Injecting fluorescent dyes into both axons and their associated TSCs showed that on some occasions long TSC processes were accompanied by a long nerve terminal process and at other times they were not. It is suggested that the mature motor-nerve terminal is a dynamic structure in which the formation of processes by TSCs guides nerve terminal sprouting.     

The fine structure of pacemaker cells in the pig renal calices

Using the electron microscope, two types of smooth muscle cell have been recognized in the upper urinary tract of the pig. One type is confined solely to the renal attachment of each minor calix and possesses a number of atypical features. These cells are not grouped into bundles but form a loose meshwork. They frequently branch, are comparatively long with very irregular profiles, and are separated by relatively large amounts of connective tissue although maculae adhaerentes are occasionally observed between neighbouring cells. Dense micronbrils occur in the vicinity of the cells which are surrounded by a partial basal lamina. Groups of axons are seen in the region, many of which contain small dense-cored vesicles. Within the atypical cells, filaments are loosely packed and accumulations of micropinocytotic vesicles are not observed. These features contrast markedly with those of typical muscle cells in other regions of the upper urinary tract where they form tightly packed bundles unrelated to axon profiles. The typical smooth muscle cells are larger and more regular in outline, are surrounded by a complete basal lamina, possess tightly packed filaments, and contain numerous micropinocytotic vesicles and glycogen particles. Similar modified muscle cells occur in the unicaliceal systems of other species where they are also confined to the proximal end of the urinary tract. It is suggested that the atypical cells are specially adapted to function as spontaneously active “pacemakers” initiating ureteric peristalsis.     

Ultrastructure of intramural ganglia in the striated muscle portions of the guinea pig oesophagus

The ultrastructure of the myenteric plexus located in the striated muscle portion of the guinea pig oesophagus was examined and compared with that of the plexus associated with the smooth muscle portion of the rest of the digestive tract. The oesophageal ganglia had essentially the same architecture as those of the smooth muscle portion, such as a compact neuropil without the intervention of connective tissue and blood vessels. Some features, however, were particular to the striated muscle part of the oesophagus. It was clearly demonstrated that myelinated fibres, probably sensory terminals of vagal origin, join the myenteric ganglia. Synapses and terminal varicosities are sparsely distributed within the ganglia and fewer morphological types of axon varicosities could be distinguished compared with other regions. Glial cells are well developed in the oesophageal myenteric ganglia. These cells outnumber the ganglion cells, having a higher ratio than in the lower digestive tract, and form numerous cytoplasmic lamellar processes. The lamellar processes, located at the surface of the ganglia, considerably reduce the area of neuronal membrane which directly contacts the basal lamina. The role of these lamellar processes in the oesophageal ganglia is discussed.     

Ultrastructural identification of axons supplying the M. retractor phalli cranialis in chickens

The chicken m. retractor phalli cranialis classified as a smooth muscle was examined by electron microscopy to study the innervation of this muscle using the dichromate/chromate fixation method for demonstration of biogenic amines (Tranzer and Richards, 1976). Approximately two axon complexes per 100 muscle cells were found in both sexes. The axon varicosities were divided into the following four types; varicosities with, 1) small clear vesicle and chromaffin-negative large granular vesicle (cholinergic), 2) chromaffin-positive, 6-hydroxydopamine (6-OHDA) susceptible small and large granular vesicle (adrenergic), 3) chromaffin-positive, 6-OHDA resistant pleomorphic and large granular vesicle (aminergic?), or 4) chromaffin-negative large opaque vesicle (peptidergic?). These results suggest that non-adrenergic, non-cholinergic nerve may also play an important role in the innervation of m. retractor phalli cranialis as well as of the smooth muscle in mammalian intestine.     

An electron microscopic study of the mediodorsal cerebral cortex in the lizard Agama agama

Summary An electron microscopic analysis was made of the small-celled part of the mediodorsal cortex of the lizard Agama agama. This cortex consists of four layers: Superficial plexiform layer, cellular layer, deep plexiform layer and fiber layer. In the superficial plexiform layer one type of solitary neuron with smooth dendrites is present.Three types of axon terminals can be observed: terminals with a moderately electron dense matrix packed with spherical vesicles (S1 type), axon terminals with an electron lucent matrix containing fewer spherical synaptic vesicles than the S1 type (S2 type) and axon terminals with an electron lucent matrix and scattered pleomorphic synaptic vesicles (F type). F type axon terminals are larger than S terminals. At the pial surface endfeet of tanycytic processes form a limiting glial layer, contacting one another by means of gap junctions. In the cellular layer perikarya of pyramidal neurons are densely packed. The karyoplasm of these neurons shows either evenly dispersed or discretely clumped chromatin. Spiny dendrites arise from the perikarya and extend into both the superficial and deep plexiform layers. The structure of the deep plexiform layer is roughly similar to that of the superficial plexiform layer. The fiber layer contains the majority of the afferent and efferent axons of the mediodorsal cortex. The axons are myelinated and unmyelinated. Between the fibers, scattered solitary neurons are present, often accompanied by glial cells.The lateral ventricle beneath the fiber layer is lined by a single row of ependymal tanycytes. Tanycytic processes traverse the cortical layers and may form endfeet at the pial surface. Protoplasmic excresenses from some ependymal cells protrude into the ventricle.     

Properties of nerve endings with small granular vesicles in the distal colon and rectum of the guinea-pig

The appearance and distribution of nerve endings (varicosities) containing small granular vesicles have been studied in the distal colon and rectum of the guinea-pig with the electron microscope. Two types of varicosity were recognised. They were distinguished by differences in their synaptic vesicles and in their distribution in the layers of the gut wall. The first type resembled noradrenergic nerves in having predominantly (92%) small vesicles and few (8%) large granular vesicles (90 nm diameter). This type was common in the plexuses and at the medial-adventitial border of arteries and arterioles but was sparsely distributed in the muscle coat. The second type had a lower proportion of small vesicles (69%) and a higher proportion (31%) of large granular vesicles (132 nm diameter). This type was absent in Auerbach's plexus, well represented in the muscle coat and Meissner's plexus and not associated with blood vessels. The first type was labelled with 5-hydroxydopamine, a specific marker for noradrenergic nerves, and disappeared after extrinsic denervation. a procedure which causes degeneration of noradrenergic nerves in the gut. The second type was unaffected by 5-hydroxydopamine and extrinsic denervation.It is concluded that the two types of small granular vesicle-containing varicosities belong to different axons and that the first type is noradrenergic. The second type of nerve axon has not been described in the gut before and is intrinsic to it. From the distribution and numbers of these axons in the circular muscle it would seem that they play an important role in gut motility.     

Interrelations of basket cell axons and climbing fibers in the cerebellar cortex of the rat

Summary An analytical study was undertaken with both electron microscopy and the rapid Golgi method in order to clarify the interrelations of climbing fibers, basket cell axons, and Purkinje cell dendrites. The two fibers are readily distinguished in electron micrographs by means of their differing content of microtubules and neurofilaments, the packing density of synaptic vesicles, and the disposition of their synaptic junctions on the Purkinje cell dendrite. Climbing fibers are generally thin and contain many microtubules. They give off attenuated collaterals, whose rounded varicosities are densely packed with vesicles and which form en passant synapses with clusters of thorns projecting from the major Purkinje dendrites. In contrast, basket axons are relatively thick and contain many neurofilaments. By means of slight dilatations containing loosely aggregated vesicles, the axon and its collaterals form numerous synapses en passant with the smooth dendritic shafts and the perikaryon of the Purkinje cell. Climbing fibers and basket cell axons run along parallel with each other but without forming axo-axonic synapses as they ascend over the surface of the Purkinje dendrites. Both fibers form especially elaborate intertwined festoons at the branching points of the major dendrites. The kinds of synapses found are described in detail, and the functional implications are discussed.The hypothesis is developed that the dendritic thorn is a device for isolating the subsynaptic membrane from electrical events in the rest of the dendrite at the cost of reducing the effectiveness of the synapse. This principle is incorporated in the Purkinje dendrite—parallel fiber synapses, in which an individual fiber can be expected to have little importance. The disadvantage of using thorns as postsynaptic surfaces can be mitigated by clustering them and increasing the number of thorns contacted by each presynaptic terminal. This method is utilized at the junctions between the climbing fiber and the Purkinje dendrite to produce one of the most powerful excitatory synapses known. It is furthermore suggested that the elaborate plexus of climbing fibers and basket cell axons synapsing in the crotches of branching dendrites is strategically located to control the flow of information in the Purkinje cell dendritic tree.Supported by U.S. Public Health Service Research Grant NS03659 and Training Grant NS05591 from the National Institute of Neurological Diseases and Stroke.Postdoctoral trainee in Anatomy under Training Grant GM906 from the National Institute of General Medical Sciences.     

Characterization of the interstitial cells associated with the submuscular plexus of the guinea-pig colon

Interstitial cells associated with the submuscular plexus of the guinea pig colon were studied by electron microscopy and by light microscopic wholemount stretch preparations. Their cytoplasmic features are similar to those of fibroblasts and they contain a well-developed Golgi apparatus, granular endoplasmic reticulum and many mitochondria. Intermediate filaments are abundantly distributed throughout the perinuclear region and processes. Numerous caveolae, a basal lamina and subsurface cisterns are observed on the cell membrane as in smooth muscle cells. The most characteristic feature of this cell type is the existence of many large gap junctions that interconnect these cells to each other and with the smooth muscle cells. Nerve varicosities containing synaptic vesicles are observed in close apposition with cells of this type. Whole-mount preparations stained by the zinc iodide-osmic acid method and by vimentin immunohistochemistry clearly demonstrated the stellate form of these gap junction-rich cells and suggested that they correspond to the interstitial cells of Cajal.     

Ultrastructure of sympathetic axons and their structural relationship with vascular smooth muscle

This review focuses on the more recent findings of the structure of sympathetic postganglionic axons and the association of their varicose terminals with vascular smooth muscle. These studies have investigated the innervation of a wide range of vessels from different regions of the vasculature in the rat, guinea pig and rabbit and have predominantly used serial sections and computerised three-dimensional reconstructions of entire varicosities. They have shown, contrary to previous studies conducted in the 1960s and 1970s, that sympathetic axon varicosities commonly form structurally specialised neuromuscular junctions with vascular smooth muscle cells of most resistance arteries and some small veins. In addition, they have shown that most axon varicosities innervating small arterioles and small mesenteric veins form neuromuscular junctions, indicating that neurotransmitter is primarily released at such neuromuscular junctions. This review discusses the structure of sympathetic neuromuscular junctions, their development, structural diversity and distribution on vessels from different regions of the vasculature. These more recent structural findings and their possible significance for our understanding of mechanisms involved in neural transmission in blood vessels is discussed.     

Mucosal nerves and smooth muscle relationships with gastric glands of the opossum: An ultrastructural and three-dimensional reconstruction study

The precise anatomical relation by which autonomic nerve endings contact gastric epithelial cells to enhance the rate of gastric secretions is not fully understood. The aim of the present study was to clarify this issue by using the technique of serial section reconstruction of areas of the gastric mucosa. The work also explored the possibility of a functional role for a system of smooth muscle strands in the gastric mucosa that emanate from the muscularis mucosa, run in the lamina propria, and are associated in a unique manner with the gastric glands. Electron microscopic serial sections of the gastric mucosa were performed to visualize the entire limiting membrane of gastric epithelial cells to determine any nerve associations (especially varicose endings) with these cells. Evaluation of serial sections of five separate parietal cells showed that their basal membrane did not come in close contact (nearest distance 500 nm) with any nerve axon or varicosity. Moreover, the axons passing in the area of these cells ultimately showed varicose endings associated with smooth muscle cells in the adjacent connective tissue (often separated by only 20 nm), with mast cells or with vascular elements. Additionally, the lateral membrane of these five parietal cells did not contact any endocrine cell in the epithelium, although other parietal cells in the area were adjacent to endocrine cells. Chief cells in the immediate area also did not form any close associations with nerve varicosities. Random analysis of 5,000 additional epithelial cells in these sections showed no close associations to nerve elements with significant accumulations of neurosecretory vesicles (varicosities). Because of the observed existence of innervation to the smooth muscle strands in the area of the gastric glands, serial 1-μm epoxy sections of the gastric mucosa were prepared, and profiles of smooth muscle and gastric glands were entered into a computer-assisted reconstruction system. Three-dimensional reconstruction techniques were employed to reveal the existence of a unique association between the mucosal smooth muscle strands and the gastric glands. The muscle strands arose from the muscularis mucosa at regular intervals and became branched to form an intricate wrap around a series of gastric glands that empty into one gastric pit. Branching of the muscle strands initially occurred at the point where they approached the base of the glands and then emanated into the connective tissue around the glands in a crossing pattern, ending at the base of the gastric pit. Although muscarinic agents have been shown to directly stimulate parietal cells to secrete acid, these findings have led us to postulate that autonomic nerve stimulation may also aid gastric secretion both by stimulation of mast cells and by glandular excretion mediated via mucosal muscular contractions.     

The structural relations between nerve fibres and muscle cells in the urinary bladder of the rat

Summary Intramuscular nerve fibres in the bladder of adult female rats were investigated by means of serial sections. The following observations were made. (1) Upon penetrating into the musculature the nerve bundles branch repeatedly, and almost all turn into single fibres; their axons become varicose, the Schwann cell sheath is attenuated, incomplete or absent, and the separation between axonal membrane and muscle cell membrane is reduced to tens of nanometres. (2) All single axons, and some of those within bundles, are varicose, but the characteristic of being varicose is expressed by degrees, and is not an all-or-none state. (3) Varicosities contain vesicles (mostly of the agranular type), microtubules (with little connection with the axolemma or the vesicles), some neurofilaments (scarce or absent in the best developed varicosities), mitochondria (whose size is on average smaller than those of the perikaryon, and a minute amount of endoplasmic reticulum. (4) Terminal varicosities, the true anatomical ending of an axon, are often devoid of Schwann cell sheath, are packed with vesicles, rarely contain microtubules or neurofilaments, and lie close to a muscle cell: the gap is often reduced to 10 nm. (5) Schwann cells accompany the axons within the muscle strands. Unlike the area of the axonal profiles, the area of glial sheath changes little along the length of the nerve fibre, except towards its end. (6) The Schwann cell sheath around a varicosity is often incomplete; the area of the axolemma thus exposed is covered by the basal lamina, and is here referred to as a window. While some varicosities have a window only a few tens of nanometres in width, others have more than one window, and some are devoid of Schwann cell altogether, so that their entire axolemma is in contact with the basal lamina. The Schwann cell never extends beyond the axon, whereas very often (and possibly always) the axon extends beyond the Schwann cell. (7) Intervaricose segments vary in length and diameter, the narrowest ones accompanying the more clear-cut varicosities. Some intervaricose segments are as small as 50 nm in diameter, contain a single microtubule and lack a Schwann cell sheath. Others, sheathed by a Schwann cell, contain a single neurofilament or no organelles at all. (8) Specialized contacts between an axon and a muscle cell (neuro-muscular junctions) are abundant and are identified by four features: the axon is a varicosity packed with vesicles; the axolemma is exposed (presence of a window); the distance between the two membranes ranges between 10 and 100 nm, mostly 30–50 nm; and the intercellular gap excludes fibrils, such as collagen, but is occupied by a single basal lamina. Any of these parameters, however, can also occur uncoupled (windows on intervaricose segments; varicosities without a window; exposed axolemma far from a muscle cell). (9) There are no direct contacts between axons. Even when they run close to each other within a bundle, they are always separated by a Schwann cell process. (10) The muscle cell membrane is concave beneath the varicosities; however, the muscle cell ultrastructural features in the region of the neuro-muscular junction are not different from those in other regions of the cell. (11) On average there is more than one neuro-muscular junction per muscle cell, and examples of muscle cells receiving multiple nerve endings from one or from two axons are picked up by the serial sections. (12) A striking feature of the bladder innervation is the variability of its ultrastructural parameters. The bladder innervation does not appear to be built on a rigid structural plan, and the notion of loose-patterned innervation is presented.     

Localization of tritiated norepinephrine in the renal arteriolar nerves

The innervation of the glomerular arterioles was investigated by light and electron microscopy autoradiography for localization of exogenous tritiated norepinephrine. By light microscopy accumulations of grains were seen associated with afferent arterioles and in lesser numbers with efferent arterioles and neighboring tubules. Accumulations of grains were noted to be in contact with juxtaglomerular granular cells. Electron microscopy autoradiography revealed that nearly two-thirds of the silver grains were on axons. Most of the label was on varicosities packed with small, clear and dense-cored, vesicles. Most varicosities, including those in contact with smooth muscle, juxtaglomerular granular or tubular cells, were labeled. Some varicosities which appeared unlabeled in a given section were labeled in subsequent sections. These findings are consistent with the notion that the glomerular arterioles are innervated mainly by adrenergic nerves. This view is supported by the previously reported observations of the concomitant virtual disappearance of fluorescent and acetylcholinesterase-positive nerves from the region of the glomerular arterioles after two injections of six-hydroxydopamine (a drug which selectively destroys adrenergic nerves) and the presence of small dense-cored vesicles in all axons of the juxtaglomerular region when examined by serial section electron microscopy.     

A study of excitatory neuromuscular transmission in the bovine trachea

1. The excitatory innervation of bovine tracheal smooth muscle has been studied with the sucrose-gap apparatus.2. Single 2 ms electrical stimuli applied to the whole tissue excited intrinsic nerves, and produced a small transient depolarization of the smooth muscle, the excitatory junction potential (e.j.p.). The e.j.p. caused a twitch-type contraction; twitches and e.j.p.s summated during repetitive stimulation but facilitation was not observed, and action potentials were never elicited.3. The effects of electrical stimulation could be abolished by atropine (5 x 10(-7) mol/l) and augmented by neostigmine (4 x 10(-6) mol/l), and were mimicked by exogenous acetylcholine (1.0 mug/ml).4. With the electron microscope, the density of innervation was found to be low (one axon per ninety smooth muscle cells). Axons were found in small groups in the clefts between bundles of cells, but no axons penetrated within the muscle bundles. Naked axon varicosities containing agranular vesicles were seen, but no axon approached within 200 nm of a smooth muscle cell.5. It is difficult to reconcile the sparsity of innervation with the dependence of the tissue on nerve excitation to initiate activity.     

The recurrent collaterals of Purkinje cell axons: A correlated study of the rat's cerebellar cortex with electron microscopy and the Golgi method

Summary Each Purkinje cell axon with its recurrent collaterals occupies a roughly triangular space in the folium, apex pointed towards the white matter and base against the Purkinje cell layer. The axon is smooth initially but develops distensions that become more obvious at twists and turns and at points where collaterals originate. These thin, finely beaded collaterals make characteristic acute angles with the axon from which they issue. The collaterals bifurcate further, their terminal branches becoming more varicose, intertwining with each other to form plexuses in the molecular and granular layers. These fiber plexuses are found in three locations: (1) the recurrent collateral plexus in the granular layer which synapses with dendrites and somata of deep Golgi II neurons; (2) the profuse infraganglionic plexus, boutons of which terminate in relation with the somata and dendrites of Purkinje cells and Lugaro cells, in addition to participating in other complex synaptic arrangements in the neuropil; (3) the sparse supraganglionic plexus which forms synapses with dendrites of Purkinje cells and occasionally with basket cells.In electron micrographs, terminals belonging to recurrent collaterals contain a mixture of neurofilaments, microtubules, and slender mitochondria with a loose array of flat, elliptical, and round synaptic vesicles embedded in a dark filamentous matrix. It is usual to find a cluster of boutons on the postsynaptic surface. Each synapse consists of several separate macular junctional complexes. The synaptic cleft is widened and contains a dense fibrous material while both pre- and postsynaptic components have very shallow, symmetrical filamentous densities adherent to the cytoplasmic surfaces of the membranes.It is suggested that recurrent collaterals from axons of Purkinje cells may provide a rapid monosynaptic feed-back mechanism for inhibitory control of Purkinje cell responses. These collaterals may also participate in a slower positive feed-forward circuit or resetting mechanism involving at least two synapses. The existence of this circuit is indicated by synapses on deep Golgi II neurons. The inhibition of Golgi II cells may depress their inhibitory activity on surrounding granule cells, thus resetting the mechanism for the subsequent responses to excitatory afferent input. Recurrent collateral inhibition also may aid in the disinhibition of Purkinje cells through the depression of basket cell activity.Supported by U.S. Public Health Service Research Grant NS03659 and Training Grant NS05591 from the National Institute of Neurological Diseases and Stroke.     

Development and fine structure of murine Purkinje cells in dissociated cerebellar cultures: neuronal polarity

 Cerebellar Purkinje cells (PC) display a highly distinctive form of polarity. We have cultured murine PCs from dissociated E16 cerebellar anlagen for 1 week to investigate the early stages of neuronal compartmentalization and synaptic interactions, features which are important for the establishment of neuronal polarity. To unequivocally identify the PCs we utilized light and electron microscopic immunocytochemistry with an antiserum to the cell class-specific marker L7/pcp2 gene product. The PCs typically show a single, long axon, numerous short appendages classified as filopodia and protospines, and a small number of protodendrites. The nucleus is positioned asymmetrically in both the horizontal and vertical axes of the soma. The Golgi apparatus, coated and uncoated vesicles, and mitochondria are prominent ultrastructural features, while the endoplasmic reticulum is highly fragmented. The cell body receives rudimentary synapses on its smooth surfaces and appendages and no consistent morphological differences were detected between these elementary contacts. The axon is clearly identifiable; it emanates from either the cell body or a protodendrite, bifurcates at predominantly right angles, forms beaded collaterals, and terminates with relatively large growth cones. The varicosities of the PC axon contain pleomorphic synaptic vesicles and form rudimentary synapses primarily with the dendritic shafts of immunonegative neurons. The protodendrites are short, quickly tapering and sparsely branched; they emit numerous filopodia and immature spines and terminate with small growth cones. Rudimentary synapses are received on the proximal dendritic shafts and filopodia, and more mature synapses occur frequently on protospines. With few exceptions, PCs lie atop an astrocytic bed layer and glial processes are apposed to the various aspects of the PC body left free by the afferent axons. By contrast, PC processes are largely free of glial sheaths. We conclude that the ”stellate stage” of PC development in situ is replicated rather faithfully in culture and that PCs have established polarity and have begun to form intercellular contacts by 1 week in vitro. Moreover, the PCs are already morphologically distinct from other cell types in the 1-week cultures, although they have yet to develop the differentiated features that distinguish mature PCs. Accepted: 30 June 1997     

Ultrastructural localization of neurotensin immunoreactivity in the stellate ganglion of the cat

Summary The morphological features and cellular relationships of neurotensin-containing axon terminals were studied at light and electron microscopic levels in the cat stellate ganglion using peroxidase and immunogold immunocytochemistry. By light microscopy, neurotensin immunoreactivity was detected within thin varicose fibres distributed throughout the ganglion. Immunoreactive fibres were no longer apparent following chronic deafferentation of the ganglion indicating that they were of extrinsic origin. Ultrastructural analysis of peroxidase immunostained material confirmed the presence of neurotensin immunoreactivity within a subpopulation of axonal varicosities which made synaptic contacts with the dendrites of ganglion cells. Within labelled varicosities neurotensin immunoreactivity was found by both immunoperoxidase and immunogold methods to be concentrated within large dense core vesicles 80–120 nm in diameter. These large dense core vesicles were characteristically distant from the active zone, in keeping with a possible extrasynaptic release of the peptide.     

Specialised sympathetic neuroeffector associations in rat iris arterioles

Vascular sympathetic neuroeffector associations have been examined in rat iris arterioles using serial section electron microscopy and reconstruction techniques. Examination of random sections showed that, of all profiles of varicosities (199) seen to lie closer than 4 μm to vascular smooth muscle cells, only a small proportion (29/199) were found in close association with vascular smooth muscle cells, where adjacent membranes were separated by less than 100 nm. However, serial section examination, from intervaricose region to intervaricose region, of 79 varicosities similarly observed lying within 4 μm of vascular smooth muscle cells showed that 54 formed close associations with vascular smooth muscle cells. In serial sections, all these varicosities were also closely associated with melanocytes and of the 25 remaining varicosities, 22 formed close associations with melanocytes alone, whilst 3 did not come into close association with any effector cell. The increased observation of close associations with vascular smooth muscle cells in serial sections, compared with random sections, is consistent with the demonstration that the area of contact only occupies, on average, a small percentage (5%) of the total surface area of the varicosity as seen in the 3-dimensional reconstructions. In both random and serial sections, close associations were observed between varicosities and vascular smooth muscle cells or melanocytes irrespective of whether fibres were present singly or in small nerve bundles. Three-dimensional reconstruction of associations of varicosities and vascular smooth muscle cells demonstrated several common features, such as accumulations of synaptic vesicles and loss of Schwann cell covering at the region of membrane facing the effector cell. The similarity in the appearance of the neuroeffector association seen in this study and those described in previous studies provides evidence for the existence of a common sympathetic neuroeffector association, irrespective of the receptor subtype involved in neurotransmission.