Electron microscopic study on the innervation of the pancreas of the domestic fowl

Summary The innervation of the pancreas of the domestic fowl was studied electron microscopically. The extrapancreatic nerve is composed mostly of unmyelinated nerve fibers with a smaller component of myelinated nerve fibers. The latter are not found in the parenchyma. The pancreas contains ganglion cells in the interlobular connective tissue. The unmyelinated nerve fibers branch off along blood vessels. Their synaptic terminals contact with the exocrine and endocrine tissues. The synaptic terminals can be divided into four types based on a combination of three kinds of synaptic vesicles. Type I synaptic terminals contain only small clear vesicles about 600 Å in diameter. Type II terminals are characterized by small clear and large dense core vesicles 1,000 Å in diameter. Type III terminals contain small clear vesicles and small dense core vesicles 500 Å in diameter. Type IV terminals are characterized by small and large dense core vesicles. The exocrine tissue receives a richer nervous supply than the endocrine tissue. Type II and IV terminals are distributed in the acinus, and they contact A and D cells of the islets. B cells and pancreatic ducts are supplied mainly by Type II terminals, the blood vessels by Type IV terminals.This work was supported by a scientific research grant (No. 144017) and (No. 136031) from the Ministry of Education of Japan to Prof. M. Yasuda     

Fine structure of synapses in the hippocampus of the rabbit with special reference to dark presynaptic endings

Summary The stratum radiatum of h ₃ and h ₄ in the hippocampus of the rahbit, where the mossy fiber endings are distributed, was investigated under the electron microscope. These regions contain a certain number of electron dense presynaptic endings. These are characterized by highly dense synaptic vesicles and mitochondrial matrices. The dense endings are not considered as degenerated. Electron dense silver particles, substituted for zinc, occurred on the synaptic vesicles of these dense terminals as well as the mossy fiber endings after the application of Timm's histochemical method modified for electron microscopy. It is concluded that the dark synaptic endings observed might represent mossy fiber terminals in a special functional phase, or might be the result of structural alteration in the course of tissue preparation. The zinc localized in the synaptic vesicles is thought to be associated with the neurotransmitter present in these endings.     

ATP-Dependent calcium uptake by cholinergic synaptic vesicles isolated fromtorpedo electric organ

Summary Cholinergic synaptic vesicles were purified fromTorpedo electric organ to near morphological homogeneity. They were isolated in a K⁺ environment. A method is described for the preparation of concentrated synaptic vesicles that allows uptake studies by conventional techniques. An ATP-Mg-dependent calcium uptake associated with synaptic vesicles is characterized. The uptake system transports calcium against a high concentration gradient. The maximum accumulation rate is obtained for the calcium, Mg⁺⁺ and ATP concentrations likely to be found in the nerve terminal cytoplasm. It is suggested that synaptic vesicles are implicated in the removal of the calcium entering the nerve terminal during synaptic activity.     

Polyhedral Protein Cages Encase Synaptic Vesicles and Participate in Their Attachment to the Active Zone

In an effort to elucidate the interactions between synaptic vesicles and the membrane of the active zone, we have investigated the structure of interneuronal asymmetric synapses in the neocortex of adult rats using thin-sectioning, freeze-fracture, and negative staining electron microscopy. We identified three subtypes of spherical synaptic vesicles. Type I were agranular vesicles of 47.5 ± 3.8 nm (mean SD,n = 24) in diameter usually seen aggregated in clusters in the presynaptic bouton. Type II synaptic vesicles were composed of a ∼45-nm-diameter lipid bilayer sphere encased in a cage 77 ± 4.6 nm (mean SD,n = 42) in diameter. The cage was composed of open-faced pentamers 20–22 nm/side arranged as a regular polyhedron. Type II caged vesicles were found in clusters at the boutons, adhered to the active zone, and were also present in axons. Type III synaptic vesicles appeared as electron-dense spheres 60–75 nm in diameter abutted to the membrane of the active zone. Clathrin-coated vesicles and pits of 116.6 ± 9 nm (mean SD,n = 14) in diameter were also present in both the pre- and postsynaptic sides. Freeze-fracture showed that some intrinsic membrane proteins in the active zone were arranged as pentamers exhibiting the same dimension of those forming cages (∼22 nm/side). From these data, we concluded that: (a) the presynaptic bouton contains a heterogeneous population of “caged” and “plain” synaptic vesicles and (b) type II synaptic vesicles bind to receptors in the active zone. Therefore, current models of transmitter release should take into account the substantial heterogeneity of the vesicle population and the binding of vesicular cages to the membrane of the active zone.     

An ultrastructural study of the polyp and strobila of Atorella japonica (Cnidaria,Coronatae) with respect to muscles and nerves

Atorella japonica were observed by TEM to examine the nerve plexus in the capitulum of the polyp and the cross-striated muscle cells of the strobila. The nerve plexus included a number of neuromuscular junctions and many interneural synapses. Neuromuscular junctions contained two types of synaptic vesicle: clear and small (ca 75 nm diam.), and dense cored and large (ca 120 nm diam.). The first type of vesicle always appeared near the presynaptic membrane and the second type was distributed behind the former. In interneural synapses, two types of vesicle which were similar to neuromuscular synaptic vesicles were recognized. They were distributed in a pattern similar to that of the neuromuscular synaptic vesicles, but these vesicles were found on both sides of the two synaptic membranes.     

The high-molecular-weight proteins of bovine brain plain synaptic vesicles

High molecular mass polypeptides (M _r >100,000) of plain synaptic vesicles from bovine cerebral cortex were separated using porous polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. Four major bands, ofM _r 262,000, 249,000, 216,000, and 173,000, were resolved. Investigations into the membrane association of theM _r 216,000 and 173,000 proteins by means of solubilization experiments and Sepharose 4B chromatography indicate that the former is a peripheral protein and the latter is more firmly attached, possibly an integral protein. Finally, theM _r 216,000 protein was shown to be highly enriched in synaptic vesicles compared to other brain subfractions. It thus appears to be specifically associated with synaptic vesicles and therefore may have an important role specific to synaptic vesicle function or structure.     

Ultracytochemical localization of acetylcholine-like cations in excited motor end-plates by means of ionic fixation

Summary Using rapid ionic fixation with molybdic or tungstic heteropolyanions (strong precipitating agents of quaternary ammonium cations such as choline and acetylcholine), acetylcholine-like cations were localized aspoint-like precipitates in the synaptic vesicles of resting (electrically nonstimulated) motor nerve terminals. When performed at low temperature, the same procedure revealedspot-like precipitates (presumed to be exocytotically released acetylcholine-like cations) in the synaptic cleft in the vicinity of the active zone. These precipitates were often seen in paired forms. Unlike resting motor-nerve terminals, excited terminals (electrical stimulation with occasional 4-aminopyridine pretreatment) after ionic fixation exhibited, at first,laminar precipitates both in the vicinity of the active zone inside the nerve terminals and in the synaptic space. In the vicinity of the active zone, the laminar precipitates were directed towards the synaptic membrane, while those in the synaptic space showed no orientation. Ionic fixation also revealeddiffused precipitates both around the synaptic vesicles and on the axoplasmic side of the presynaptic membrane. Finally, the same fixation procedure demonstrated the presence of empty synaptic vesicles (without point-like precipitates) in close contact with the presynaptic membrane. The laminar and diffused precipitates are presumed to be two different forms of the same salts of acetylcholine-like cations that are insolubilized by ionic fixation in both the nerve terminals and the synaptic space of excited motor end-plates.     

Synaptic and Synaptoid Vesicles Constitute a Single Category of Inclusions: New Evidence From Invertebrate Nervous Systems

Parallel observations on synaptic and neurohaemal terminals in the polychaete annelids Nereis diversicolor and Harmothoe imbricata have revealed a remarkable identity of ultrastructure. Even features peculiar to the synaptic vesicles of polychaetes are mirrored by those of synaptoid inclusions. A wide range of terminal types show a clear duality of secretory inclusions, featuring both ‘storage granules’ and synaptic/synaptoid vesicles. The inclusions exhibit a marked zonation. Vesicles form tight clusters with interstitial dense material in many terminals and these make contact with release sites. Terminals containing larger, typically peptidergic granules often have mainly dense-cored synaptic/synaptoid vesicles, although some such inclusions are present in other endings also. A variety of synaptic associations are present, and ‘serial synaptoids’ are formed by neurohaemal terminals. The results are interpreted to suggest that synaptic and synaptoid vesicles have a common functional significance.     

Synaptic ribbons during postnatal development of the pineal gland in the golden hamster (Mesocricetus auratus)

Summary Synaptic ribbons, functionally enigmatic structures of mammalian pinealocytes, were studied during the postnatal development of the pineal gland in the golden hamster (Mesocricetus auratus). On day 4 post partum, synaptic ribbons appear in cells that have already started to differentiate into pinealocytes. Between days 4 and 9, an increase in the number of synaptic ribbons occurs, concomitant with the continuing differentiation of the pineal tissue. Between days 9 and 16, when differentiation of this tissue is almost completed, the number of synaptic ribbons decreases and approaches that characteristic of the adult pineal gland. During development, the synaptic ribbons increase in length, and dense core vesicles are frequently found in the vicinity of these structures. It is assumed that a functional relationship exists between dense core vesicles and the synaptic ribbons, which are considered to be engaged in a certain form of secretory activity of the mammalian pineal gland.Supported by the Deutsche Forschungsgemeinschaft     

The ultrastructure of giant fibre and serial synapses in crayfish

Summary The ultrastructure of synapses between the cord giant fibres (lateral and medial) and the motor giant fibres in crayfish, Astacus pallipes, third abdominal ganglia have been examined. These electrotonic synapses are asymmetrical, they have synaptic vesicles only in the presynaptic fibre, and they have synaptic cleft widths normally of about 100 Å but narrowed to about 50 Å in restricted areas. Localized increases in density of the synaptic cleft and adjacent membranes also occur within a synapse, and synaptic vesicles are most tightly grouped at the membrane in such areas. Tight or gap junctions with 30 Å or narrower widths have not been found, but the junctions probably function in a similar way to gap junctions.Three small nerves are closely associated with the synapses between the giant fibres. One of these small nerves has round synaptic vesicles and is thought to be excitatory on morphological grounds; one has flattened vesicles and is thought to be inhibitory; and one is postsynaptic to the lateral giant and the two small presynaptic nerves. It is proposed that these small nerves modulate activity in the much larger giant fibre synapse.     

Diurnal variations in the photoreceptor synaptic terminals of the newt retina

Newt photoreceptor synaptic terminals undergo a variety of morphological changes over a 24-hr (LD 12:12) cycle. During the day, dense-cored synaptic vesicles were found to increase in number and accumulate near the synaptic lamellae; during the dark phase, the dense-cored vesicles decreased in number, while large clear vesicles and profiles of smooth endoplasmic reticulum increased in frequency. The most marked change in photoreceptor synaptic terminal morphology occurred after 10 hr of darkness, at 0730 hr. At this time, photoreceptor synaptic terminal cross-sectional area was found to increase dramatically. Morphometric analysis showed that the number of synaptic vesicles in these terminals remained constant throughout the day, as did the perimeter of photoreceptor terminal profiles. The observed increase in area of synaptic terminals at 0730 hr was found to be due to a decrease in the folding of the terminal plasma membrane. Qualitative observations showed endocytosis to be occurring at a rapid rate at this time as well; and since the number of synaptic vesicles and terminal perimeter did not change, exocytosis of synaptic vesicles was assumed to be occurring at an equally rapid rate. These findings support an extension to the hypothesis of Monaghan and Osborne (1975), suggesting that photoreceptor synaptic vesicles become "supercharged" with transmitter substance in the light.     

The fine structure of the central synaptic contacts on an identified crustacean motoneuron

Summary Small nerve terminals in the neuropile of the brain of the crab Scylla serrata make close contact with the secondary, tertiary and higher order central branches of the reflex eye-withdrawal motoneurons. Most contacts have the characteristics of chemically transmitting synapses in that the presynaptic terminals contain agranular vesicles of 25 to 50 nm in diameter and are separated from the motoneuron by a synaptic cleft of about 16 nm. Some terminals contain synaptic ribbons, others contain a mixture of larger (50 to 80 nm) agranular and also dense cored vesicles. In addition large blunt-ended contacts unaccompanied by vesicles, occur between neurons in the neuropile and the motoneuron. It is suggested that the absence of synaptic contacts over the large primary branches of the motoneuron could explain previous physiological findings that little or no resistance changes can be detected in this part of the neuron during excitation or inhibition.We thank Mrs. Joan Goodrum for the preparation of Fig. 1.     

Isolation of Cholinergic Synaptic Vesicles from the Myenteric Plexus of Guinea-Pig Small Intestine

The acetylcholine-rich myenteric plexus-longitudinal muscle preparation of the guinea-pig small intestine has been subjected to subcellular fractionation using modifications of both classical methods and that originally devised for bulk isolation of cholinergic synaptic vesicles from the electromotor nerve terminals of Torpedo marmorata by means of density gradient centrifugation in a zonal rotor. The latter method gave a vesicle fraction with the highest acetylcholine content so far recorded for a mammalian particulate fraction, 30.9 × S.E.M. 1.8 (5) nmol of acetylcholine × mg of protein^?1. Electron-microscopical examination showed that it consisted of a homogeneous preparation of vesicles of mean spherical diameter 61 ×sd 4 (108) nm, with little or no contamination with other lipoprotein membrane structures, mixed how-ever with considerable amounts of actomyosin fibrils, presumably derived from the longitudinal muscle. Slab-gel electrophoresis in sodium dodecyl sulphate showed that, in addition to prominent peaks attributable to actin and myosin, there was a relatively simple pattern of (presumably) vesicle protein among which all the proteins thought to be characteristic of Torpedo synaptic vesicles were present. Dowe G. H. C. et al. Isolation of cholinergic synaptic vesicles from the myenteric plexus of guinea-pig small intestine. J. Neurochem. 35, 993–1003 (1980).     

Differences in the osmotic fragility of recycling and reserve synaptic vesicles from the cholinergic electromotor nerve terminals of Torpedo and their possible significance for vesicle recycling

In this study we demonstrate differences in the osmotic fragility of two metabolically and physically heterogeneous synaptic vesicle populations from stimulated electromotor nerve terminals. When synaptic vesicles isolated on sucrose density gradients are submitted to solutions of decreasing osmolarity 50% of VP₂-type vesicles lysed at (mean + S.E. (number of experiments)) 332 ± 14 (4) mosM and 50% of VP₁-type vesicles lysed at 573 ± 8 (3) mosM. These results indicate that recycling vesicles are more resistant to hypo-osmotic lysis and they are consistent with our earlier conclusion that changes in water content on recycling are secondary to changes in the content of the osmotically active small-molecular-mass constituents acetylcholine and ATP.     

Diurnal changes in the fine structure of photoreceptors in an abalone,Nordotis discus

Summary The ultrastructure of the synapses in the brain of the monogenean Gastrocotyle trachuri (Platyhelminthes) is described. The synapses consist of one presynaptic terminal separated by a uniformly wide synaptic cleft, from one or more postsynaptic elements. The presynaptic terminals are characterized by the presence of paramembranous dense projections and associated synaptic vesicles. The postsynaptic elements while possessing membrane densities, are usually devoid of vesicles.The structure of the synapses in the brain of Gastrocotyle is compared to synapses from other platyhelminths.     

Ultrastructural correlates of interneuronal function in the abdominal ganglion of Aplysia californica

The synaptic inputs and outputs of the major interneuron L10 of the abdominal ganglion of Aplysia were studied using an intracellular staining technique for the electron microscope. The sites of both the chemical synaptic input and output of L10 are localized to the dendritic arborizations that arise from the axon in the ganglion neuropil. Thus, the interneuronal functions are mediated at the dendritic processes and could occur in the absence of spiking in the axon and cell body. The sites of L10 synaptic output are presumed to be at. aggregations of vesicles and mitochondria in the dendrites. The synaptic vesicle content of L10, a cholinergic neuron, with many large dense vesicles resembles that described for serotonergic cells in Aplysia, making distinction of synaptic pharmacology by ultrastructure difficult. Focal membrane specializations with a clear synaptic cleft were not observed between L10 and its large population of postsynaptic cells. In contrast, clear focal input sites were frequently found on L10. Gap junctions, sites of probable electrical coupling between L10 and other neurons, were also found. These observations are discussed as evidence that many synapses do not have focal specializations.     

Ultrastructural features of neuromuscular junctions in the stapedius muscle of Gallus gallus

The ultrastructure of neuromuscular junctions in the twitch fibers of the stapedius muscle of Gallus gallus (domesticus) was investigated as part of a series of neurophysiological studies. Among the morphological features observed were elongated end-plates with numerous large and clear synaptic vesicles mixed with larger dense core vesicles and irregular or aperiodic “active sites” in the presynaptic membrane where synaptic vesicles were focused. The most remarkable features of these junctions were large synaptic clefts (50-80 nm) and the absence of junctional folds in the sarcolemmal surface. Unlike the large periodic junctional folds seen in the neuromuscular junctions of frogs and in the fast twitch fibers of the mammalian stapedius, the preparations studied only show small aperiodic invaginations (primitive folds) in the postsynaptic membranes. This morphological feature remains essentially constant from newly hatched to adult chickens. While these smooth junctions are consistent with earlier findings of inconspicuous junctional folds in the twitch fibers of the chicken posterior latissimus dorsi they are unlike those seen in the fast twitch fibers of the mammalian stapedius muscle, or other twitch fibers in general. The morphological findings of the present study may also suggest that the simple, unmodified neuromuscular junctions in the stapedius of Gallus may be a useful preparation for studies of synaptic membrane structures that employ the freeze-fracture technique.     

Studies on the turnover of mouse brain synaptosomal proteins

(l) The half-lives of the proteins of various fractions of whole mouse brain increase with increasing insolubility; the supernatant and hypotonic-extractable proteins had half-lives of about 13 days, whereas the membrane proteins solubilized with Triton X-100 and SLS had half-lives of about 18 days. The proteins of the subfractions of synaptosomes had half-lives ranging from 15 to 19 days; those in the cytoplasm had a half-life of 18·3 days, in the membranes, about 17 days and in the synaptic vesicles, 15·6 days. (2) Although the half-life of the synaptic vesicles was not significantly different from that of other synaptosomal subfractions, the vesicles exhibited a different protein pattern on acrylamide gels, an observation which implies that the proteins of the vesicles are qualitatively different from those of other synaptic membranes. (3) The uptake of labelled lysine into the cytoplasm of the synaptosomes of youg mice in vivo was very rapid. (4) The data derived from the relative specific radioactivities of synaptosomal fractions compared with their whole brain analogs support the contention that a sizeable fraction of the synaptosomal cytoplasmic protein was transported to the synapse by axoplasmic flow. The relative specific radioactivities of synaptosomal membrane and synaptic vesicle proteins rose much more quickly than the comparable activities for the cytoplasmic material, and the alternate possibility of synthesis in situ is discussed.     

A critical evaluation of the relationship between the presynaptic network,synaptic vesicles and dense projections in central synapses

Summary Synapses of the oculomotor nucleus of Echidna have been examined ultrastructurally with the aim of integrating data obtained from osmicated and nonosmicated PTA stained material. Particular emphasis has been laid on the relationship between the synaptic vesicles of the osmicated material and the presynaptic network and vesicular grid of the PTA material. This relationship has been explored qualitatively by examining osmicated material of varying qualities of fixation. Such material contains dense projections in addition to synaptic vesicles, and various vesicular network appearances. A variety of measurement techniques have shown that the PTA network is characterised by reticular strands, spaces, and regular hexagonal units smaller than vesicles, these observations prompting the formulation of a vesicle-network coincidence model of the presynaptic terminal. This model has been tested by tracing the profiles of vesicles within the PTA network and comparing their size and shape frequency distributions with those of osmicated synaptic vesicles. The distributions have been found to be essentially similar, suggesting that vesicles can be located within the network, and that the hexagonal network units are formed only in the presence of an underlying vesicular matrix.Additionally, the following points have emerged: 1) the dense projections in the two types of material appear to be equivalent; 2) a loose correlation exists between dense projections and vesicles in osmicated terminals, increase in the area of the dense projections being associated with a decrease in the area of the vesicles; 3) network and dense projection units are similar. In view of the similarity between network and dense projection units, the demonstrated vesicular basis of the network raises the question of whether dense projections are entirely independent structures, or whether they depend in part for their existence on the nearby presence of synaptic vesicles.This work was supported by the Arnold Yeldham and Mary Raine Research Foundation of the University of Western Australia and by the Australian Research Grants Committee and the Nuffield Foundation     

Serial synapses in Aplysia

Serial synapses occur between small profiles in the neuropil of Aplysia abdominal ganglion. Material was fixed in phosphate buffered OsO₄, embedded in epon, and sections were stained with uranyl acetate and lead citrate. A class of synapses had the following characteristics: (1) synaptic vesicles clustered against the presynaptic membrane, (2) a widened extracellular space of about 20 nm containing electron-dense material, (3) straightening of the pre- and postsynaptic membranes, and (4) no postsynaptic membrane specialization. Some density between the presynaptic membrane and the adjacent synaptic vesicles was occasionally observed. Synapses occurred between small profiles in the neuropil (typical profile diameters were 1–3 m?m). In this sample of approximately 100 synapses, four serial synapses were identified. The serial synaptic profiles were all small. In addition to the finding of serial synapses, 40% of the postsynaptic profiles contained vesicles similar to the synaptic vesicles seen in presynaptic profile. Serial synapses may be the anatomical substrate of presynaptic inhibition and facilitation and of dishabituation.