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 μm long) or very long thin processes (>10 μm 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 μm 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.     

Structure and ultrastructure of the frog motor endplate

Summary The frog motor endplate in its simplest form consists of an elongated, slender nerve ending embedded in a gutter-like depression of the sarcolemma. This nerve terminal contains the usual synaptic organelles. It is covered by a thin coating of Schwann cell cytoplasm which embraces the terminal with thin finger-like processes from both sides, thereby sub-dividing it into 300–1000 regularly spaced compartments. The individual synaptic compartments correspond to the strings of varicosities or grape-like configurations of motor nerve terminals in endplates of other species and in the cerebral neuropil of vertebrates.Each compartment contains one or more bar-like densities of the presynaptic membrane, active zones, which are associated with the attachment sites between synaptic vesicles and plasmalemma. Active zones have a regular transverse arrangement and occur at specific loci opposite the junctional folds. The attachment sites for synaptic vesicles are at the edges of the bars which are bilaterally delineated by a double row of 10 nm particles attached to the A-face. The structural appearance of vesicle attachment sites in freeze-etch replicas corresponds to that of micropinocytosis. The active zones are often fragmented and the frequency of their association with vesicle attachment sites is highly variable.The junctional folds are characterized by specific sites in which intramembranous particle aggregations occur at relatively high packing density (7500/m²). These sites are located opposite the active zones at the juxtaneural lips, a location where one would expect ACh-sensitive receptors on the postsynaptic membrane.This work was supported by the Deutsche Forschungsgemeinschaft (Sonderforschungsbereich 38, Projekt N), The Swiss National Foundation for Scientific Research (Grants Nr. 3 82372 and 3 77472) and the Dr. Eric Slack-Gyr Foundation Zürich.     

THE FINE STRUCTURE OF MOTOR ENDPLATE MORPHOGENESIS

The fine structure of the developing neuromuscular junction of rat intercostal muscle has been studied from 16 days in utero to 10 days postpartum. At 16 days, neuromuscular relations consist of close membrane apposition between clusters of axons and groups of myotubes. Focal electron-opaque membrane specializations more intimately connect axon and myotube membranes to each other. What relation these focal contacts bear to future motor endplates is undetermined. The presence of a group of axons lying within a depression in a myotube wall and local thickening of myotube membranes with some overlying basal lamina indicates primitive motor endplate differentiation. At 18 days, large myotubes surrounded by new generations of small muscle cells occur in groups. Clusters of terminal axon sprouts mutually innervate large myotubes and adjacent small muscle cells within the groups. Nerve is separated from muscle plasma membranes by synaptic gaps partially filled by basal lamina. The plasma membranes of large myotubes, where innervated, simulate postsynaptic membranes. At birth, intercostal muscle is composed of separate myofibers. Soleplate nuclei arise coincident with the peripheral migration of myofiber nuclei. A possible source of soleplate nuclei from lateral fusion of small cells' neighboring areas of innervation is suspected but not proven. Adjacent large and small myofibers are mutually innervated by terminal axon networks contained within single Schwann cells. Primary and secondary synaptic clefts are rudimentary. By 10 days, some differentiating motor endplates simulate endplates of mature muscle. Processes of Schwann cells cover primary synaptic clefts. Axon sprouts lie within the primary clefts and are separated from each other. Specific neural control over individual myofibers may occur after neural processes are segregated in this manner.     

The formation and function of single transmitter release sites at mature amphibian motor—nerve terminals

The extent of quantal transmitter release from single sites of synaptic vesicle accumulations along the length of motor-nerve terminal branches at the amphibian neuromuscular junction has been investigated. Such a determination involves development of a model for the generation of quantal potential fields at single styryl-dye stained sites along the length of a branch. Successful testing and application of this model indicates that the extent of quantal release at a dye-stained site is proportional to the total length of active zone at the site. The stability of these sites and of their ensheathing terminal Schwann cell processes was also investigated. Following simultaneous injection of the terminal Schwann cell and nerve terminal with different fluorescent dyes, terminal branches were observed to show dynamic changes in their length, with these occurring in relatively short periods of hours or less. Redistribution of styryl dye stained sites at the ends of branches also occurred in such short periods of time. These were accompanied by changes in the configuration of terminal Schwann cells, which generally occurred prior to changes in the length of nerve terminal branches.     

Polymorphism of myosin among skeletal muscle fiber types

An immunocytochemical approach was used to localize myosin with respect to individual fibers in rat skeletal muscle. Transverse cryostat sections of rat diaphragm, a fast-twitch muscle, were exposed to fluorescein-labeled immunoglobulin against purified chicken pectoralis myosin. Fluorescence microscopy revealed a differential response among fiber types, identified on the basis of mitochondrial content. All white and intermediate fiber but only about half of the red fiber reacted with his antimyosin. In addition, an alkali-stable ATPase had the same pattern of distribution among fibers, which is consistent with the existence of two categories of red fibers. The positive response of certain red fibers indicates either that their myosin has antigenic determinants in common with "white" myosin, or that the immunogen contained a "red" myosin. Myosin, extracted from a small region of the pectorlis which consists entirely of white fibers, was used to prepare an immunoadsorbent column to isolate antibodies specific for white myosin. This purified anti-white myosin reacted with the same fibers of the rat diaphragm that had reacted with the white, intermediate, and some red fibers are sufficiently homologous to share antigenic determinants. In a slow-twitch muscle, the soleus, only a minority of the fiber reacted with antipectoralis myosin. The majority failed to respond; hence, they are not equivalent to intermediate fibers of the diaphragm; despite their intermediate mitochondrial content. Immunocytochemical analysis of two different musles of the rat has demonstrated that more than one isoenzyme of myosin can exist in a single muscle, and that individual fiber types can be recognized by immunological differences in their myosin. We conclude that, in the rat diaphragm, there are at least two immunochemically distinct types of myosin and four types of muscle fibers: white, intermediate, and two red. We suggest that these fibers correspond to the four types of motor units described by Burke et al. (Burke, R. E., D. N. Levine, P. Tsairis, and F. E. Zajac, III 1973. J. Physiol. (Lond) 234:723-748.)in the cat gastrocnemius.`     

On the relationship of ultrastructural and cytochemical features to color in mammalian skeletal muscle

Summary The semitendinosus muscle of the albino rat is divided grossly into two clearly distinguishable parallel longitudinal bands, one red (anterior) and the other white (posterior). By using mitochondrial content as a criterion for distinguishing fiber types, it is demonstrated that the red portion of the muscle is composed predominantly of red (52%) and intermediate (40%) fibers, while the white portion consists primarily of white fibers (82%). Red fibers have the smallest and white fibers have the largest average diameter. Ultrastructural characteristics of the three fiber types resemble closely those previously described for the rat diaphragm. Red fibers are rich in large mitochondria with abundant cristae, and possess the widest Z lines. In red fibers, the H-band region of the sarcoplasmic reticulum consists of an elaborate network of narrow tubules. In white fibers, mitochondria are smaller, less numerous, and have fewer cristae; Z lines are about half as wide as in red fibers. In the H-band region of the sarcoplasmic reticulum there is a more compact arrangement of broad more or less parallel tubules. Intermediate fibers are similar to red fibers except that their diameters are larger; mitochondria are somewhat smaller and cristae are less abundant; the width of the Z lines is close to that of white fibers. The consistent difference in Z line width establishes this dimension as an important criterion for distinguishing fiber types and facilitates ultrastructural identification, especially of the intermediate fiber.The clear relationship between color of the semitendinosus and cytological features of its component fibers supports the use of the terms red, white, and intermediate as simple and valid designations for fiber types in mammalian skeletal muscle. Measurement of the cross-sectional area contributed by each fiber type to the total area indicates that both red and intermediate fibers may contribute to redness in mammalian skeletal muscle.An early portion of this work was carried out with MissSharon Whelan (Mrs.Bernard Weiss). The author acknowledges the important contribution of Mr.Richard Stearns through his skillful work on the photographic illustrations and the technical assistance of MissAnn Campbell and Mrs.Joan Normington. — This study was supported by Grant No. HD 01026-04 from the United States Public Health Service.     

Sexual differentiation of identified motor terminals in Drosophila larvae

In Drosophila, we have found that some of the motor terminals in wandering third-instar larvae are sexually differentiated. In three out of the four body-wall muscle fibers that we examined, we found female terminals that produced a larger synaptic response than their male counterparts. The single motor terminal that innervates muscle fiber 5 produces an EPSP that is 69% larger in females than in males. This is due to greater release of transmitter from female than male synaptic terminals because the amplitude of spontaneous miniature EPSPs was similar in male and female muscle fibers. This sexual difference exists throughout the third-instar: it is seen in both early (foraging) and late (wandering) third-instar larvae. The sexual differentiation appears to be neuron specific and not muscle specific because the same axon produces Is terminals on muscle fibers 2 and 4, and both terminals produce larger EPSCs in females than males. Whereas, the Ib terminals innervating muscle fibers 2 and 4 are not sexually differentiated. The differences in transmitter release are not due to differences in the size of the motor terminals. For the terminal on muscle fiber 5 and the Is terminal on muscle fiber 4, there were no differences in terminal length, the number of branches, or the number of synaptic boutons in males compared to females. These sexual differences in neuromuscular synaptic physiology may be related to male-female differences in locomotion.     

Wheat chromosome 2D carries genes controlling the activity of two DNA-degrading enzymes

DNA-degrading enzymes of 24.0 kDa and 27.0 kDa were observed to have different activities in two common wheat (Triticum aestivum L.) cultivars, Wichita and Cheyenne. A substrate-based SDS-PAGE assay revealed that these two enzymes were much more active in Wichita than in Cheyenne. Genes controlling the activities of these two enzymes were localized on chromosome 2D by testing DNA-degrading activities in reciprocal chromosome substitution lines between Wichita and Cheyenne. While the allele on Wichita chromosome 2D stimulated the activities of the 24.0- and 27.0-kDa enzymes in Cheyenne, the allele on Cheyenne chromosome 2D did not reduce the activities of the 24-kDa and 27-kDa enzymes in Wichita. Whether these genes code for the DNA-degrading enzymes themselves or for factors that regulate the enzyme activities remains unknown.This work was supported in part by USDA-Competitive Research Grants Office grant No. 90-37140-5426 to P.S.B. Contribution from Agricultural Research Division, University of Nebraska. Journal Series Number 10304     

Capillarization,mitochondrial densities,oxygen diffusion distances and innervation of red and white muscle of the lizard Dipsosaurus dorsalis

Summary The white and red regions of the iliofibularis muscle of the lizard Dipsosaurus dorsalis were analyzed using histologic and morphometric analysis. These regions are composed of fast glycolytic (FG) and both fast oxidative, glycolytic (FOG) and tonic fibers, respectively. Endplate morphology and number of endplates per fiber were estimated from fibers from both areas. Capillary volume densities of the red and white regions were quantified from transverse sections. Mitochondrial volume of fibers from the red and white regions were estimated from electron micrographs.All fibers from the white region of the iliofibularis possessed a single, well defined endplate, as did most red region fibers. The remaining red fibers (28±5%) possessed an average of 14.7±3 endplates each, distributed along the entire length of the fiber at intervals of approximately 1124 m.Red fibers possessed twice the mitochondrial volume of white fibers (7.6±0.4%, red; 3.8±0.3%, white). Mitochondria were distributed uniformly through the fibers from both regions. Capillary anisotropy was low ( = 1.018) in both regions. Capillary densities of the red region (629±35 mm^-2) were much greater than those of the corresponding White region (73±8 mm^-2).The data indicate that capillary densities, mitochondrial volumes and theoretical diffusion distances correlate well with the oxidative capacity of lizard muscle fibers. Tonic fibrs of this species appear oxidative and therefore metabolically capable of functioning during locomotion. The similar mitochondrial volumes and capillary densities of reptilian and mammalian muscles suggest that the greater oxidative capacity of mammalian muscle is due in part to possession of more oxidatively active mitochondria rather than to possession of more mitochondria per se.     

Energy metabolism of carp swimming muscles

Summary Electromyography has been used to study the recruitment of red, pink and white muscle fibres of the Mirror carp at different swimming speeds. Locomotion below 0.3–0.5 L/S (lengths per second) is achieved primarily by fin movements after which the red myotomal muscle becomes active. Pink muscle fibres are the next type to be recruited at speeds around 1.1–1.5 L/S. White muscle is only used for fast cruising in excess of 2–2.5 L/S and during bursts of acceleration.Studies of the myofibrillar ATPase activities of these muscles have shown a ratio of 124 for the red, pink and white fibres respectively. The myosin low molecular weight components, which are characteristic of the myosin phenotype, have been investigated by SDS polyacrylamide electrophoresis. The light chain patterns of the pink and white muscles were identical and characteristic of the fast myosin phenotype. Red muscle myosin had a light chain pattern characteristic of slow muscles. It would appear that there is a relationship between the speed of contraction of the fibre types and the locomotory speed at which they are recruited.The activities of some enzymes of energy metabolism have also been determined in the three muscle types. Enzymes associated with oxidate metabolism have high, intermediate and low activities in the red, pink and white muscles respectively. Pyruvate kinase and lactate dehydrogenase activities were considerably higher in the pink than in either red or white muscles. It is suggested that the high capacity for anaerobic glycolysis of the pink muscle is associated with its recruitment for sustained effort at swimming speeds above which the fish can no longer meet all its energy requirements by gas exchange at the gills.Abbreviations used EDTA ethylenediamine tetraacetic acid - L/S lengths, sec^–1 - LDH Lactate dehydrogenase - PFK phosphofructokinase - SDS sodium dodecyl sulphate - TCA trichloroacetic acid     

High -resolution scanning electron-microscopic studies on the three-dimensional structure of mitochondria and sarcoplasmic reticulum in the different twitch muscle fibers of the frog

Summary The three-dimensional structure of the mitochondria and sarcoplasmic reticulum (SR) in the three types of twitch fibers, i.e., the red, white and intermediate skeletal muscle fibers, of the vastus lateralis muscle of the Japanese meadow frog (Rana nigromaculata nigromaculata Hallowell) was examined by high resolution scanning electron microscopy, after removal of the cytoplasmic matrices.The small red fibers have numerous mitochondrial columns of large diameter, while the large white fibers have a small number of mitochondrial columns of small diameter. In the medium-size intermediate fibers, the number and diameter of the mitochondrial columns are intermediate between those of the red and white fibers.In all three types of fibers, the terminal cisternae and transverse tubules form triads at the level of each Z-line. The thick terminal cisternae continue into much thinner flat intermediate cisternae, through a transitional part where a row of tiny indentations can be observed. Numerous slender longitudinal tubules originating from the intermediate cisternae, extend longitudinally or obliquely and form elongated oval networks of various sizes in front of the A-band, then fuse to form the H-band collar (fenestrated collar) around the myofibrils. On the surface of the H-band collar, small fenestrations as well as tiny hollows are seen. The three-dimensional structure of SR is basically the same in all three muscle fiber-types. However, the SR is sparse on the surface of mitochondria, so the mitochondria-rich red fiber has a smaller total volume of SR than the mitochondria-poor white fiber. The volume of SR of the intermediate fiber is intermediate between other the two.     

The ultrastructural localization and quantitation of cholinergic receptors at the mouse motor endplate

Summary The snake venom toxin, -bungarotoxin, is known to bind specifically to the acetylcholine receptor at skeletal muscle endplates. In this study, tritiated -bungarotoxin has been used in conjunction with electron-microscope autoradiography to visualize and enumerate acetylcholine receptor sites at the neuromuscular junctions of the mouse diaphragm. From an analysis of the grain distribution, the receptor sites appear to be located specifically on the postjunctional membrane. The density there is about 8,500/² of membrane surface. For comparison purposes, cholinesterases and related active centers were labeled using [³H] diisopropylfluorophosphate; they were shown to be at this same concentration over the synaptic membranes (or along the cleft). The 11 relationship of the receptors to the cholinesterase type of site, found previously to hold in studies on whole endplates, is also true at the ultrastructural level in this case. In fact, this 11 relationship is believed to be a characteristic of the postsynaptic membranes of endplates in other muscles and other vertebrates.Based on the constant density value thus arrived at, the total surface areas of postsynaptic and of presynaptic membranes are at once obtained from the known total numbers of these sites per endplate, available from previous studies in this laboratory. Examples of such synaptic surface area values are given. These values are only reliable for a given muscle type if the approximate fiber size is defined.     

Identified motor terminals in Drosophila larvae show distinct differences in morphology and physiology

In Drosophila, the type I motor terminals innervating the larval ventral longitudinal muscle fibers 6 and 7 have been the most popular preparation for combining synaptic studies with genetics. We have further characterized the normal morphological and physiological properties of these motor terminals and the influence of muscle size on terminal morphology. Using dye-injection and physiological techniques, we show that the two axons supplying these terminals have different innervation patterns: axon 1 innervates only muscle fibers 6 and 7, whereas axon 2 innervates all of the ventral longitudinal muscle fibers. This difference in innervation pattern allows the two axons to be reliably identified. The terminals formed by axons 1 and 2 on muscle fibers 6 and 7 have the same number of branches; however, axon 2 terminals are approximately 30% longer than axon 1 terminals, resulting in a corresponding greater number of boutons for axon 2. The axon 1 boutons are approximately 30% wider than the axon 2 boutons. The excitatory postsynaptic potential (EPSP) produced by axon 1 is generally smaller than that produced by axon 2, although the size distributions show considerable overlap. Consistent with vertebrate studies, there is a correlation between muscle fiber size and terminal size. For a single axon, terminal area and length, the number of terminal branches, and the number of boutons are all correlated with muscle fiber size, but bouton size is not. During prolonged repetitive stimulation, axon 2 motor terminals show synaptic depression, whereas axon 1 EPSPs facilitate. The response to repetitive stimulation appears to be similar at all motor terminals of an axon.     

Effect of castration and testosterone administration on the neuromuscular junction in the levator ani muscle of the rat

Summary The ultrastructure of the neuromuscular junction (n.m.j.) of the androgen-sensitive levator ani muscle was studied in normal adult male rats, in 8-month-old rats castrated at the age of one month and in castrated rats treated with testosterone propionate (TP). Castration does not result in significant changes of the n.m.j. The density of synaptic vesicles and the postsynaptic junctional folds remain practically normal in spite of marked atrophy of the muscle. TP administration for 7 days results in marked changes in preand postsynaptic structures. There is slow progressive depletion of synaptic vesicles, appearance of cisternae and coated vesicles in axon terminals, and coalescence of coated vesicles with the plasma membrane. Coated vesicles are also found inside Schwann cells and among junctional folds. Dense core vesicles appear both in the axon terminals and in the postsynaptic area. Collateral sprouting of terminal axons with the formation of new immature junctions is observed. After 35 days of TP administration depletion of synaptic vesicles continues. Glycogen -particles, mostly freely dispersed, occasionally seen in axon terminals 7 days after TP administration, subsequently increase in number. In the endplate zone of the muscle fibre increased protein synthesis is indicated by a rapid increase in ribosomes and irregularly located myofilaments and myofibrils. The appearance of n.m.j. after testosterone administration resembles that described after nerve stimulation; the degree of change is however less pronounced.The authors wish to acknowledge the skillful technical assistance of Mrs. L. Vedralová     

Effect of reduced impulse activity on the development of identified motor terminals in Drosophila larvae

In Drosophila larvae, motoneurons show distinctive differences in the size of their synaptic boutons; that is, axon 1 has type Ib ("big" boutons) terminals and axon 2 has type Is ("small" boutons) terminals on muscle fibers 6 and 7. To determine whether axon 1 develops large boutons due to its high impulse activity, we reduced impulse activity and examined the motor terminals formed by axon 1. The number of functional Na(+) channels was reduced either with the nap(ts) mutation or by adding tetrodotoxin (TTX) to the media (0.1 microg/g). In both cases, the rate of locomotion was decreased by approximately 40%, presumably reflecting a decrease in impulse activity. Locomotor activity was restored to above wild-type (Canton-S) levels when nap(ts) was combined with a duplication of para, the Na(+)-channel gene. Lucifer yellow was injected into the axon 1 motor terminals, and we measured motor terminal area, length, the number of branches, and the number and width of synaptic boutons. Although all parameters were smaller in nap(ts) and TTX-treated larvae compared to wild-type, most of these differences were not significant when the differences in muscle fiber size were factored out. Only bouton width was significantly smaller in both different nap(ts) and TTX-treated larvae: boutons were about 20% smaller in nap(ts) and TTX-treated larvae, and 20% larger in nap(ts); Dp para(+) compared to wild-type. In addition, terminal area was significantly smaller in nap(ts) compared to wild-type. Bouton size at Ib terminals with reduced impulse activity was similar to that normally seen at Is terminals. Thus, differences in impulse activity play a major role in the differentiation of bouton size at Drosophila motor terminals.     

The Neuromuscular Junction: Measuring Synapse Size,Fragmentation and Changes in Synaptic Protein Density Using Confocal Fluorescence Microscopy

The neuromuscular junction (NMJ) is the large, cholinergic relay synapse through which mammalian motor neurons control voluntary muscle contraction. Structural changes at the NMJ can result in neurotransmission failure, resulting in weakness, atrophy and even death of the muscle fiber. Many studies have investigated how genetic modifications or disease can alter the structure of the mouse NMJ. Unfortunately, it can be difficult to directly compare findings from these studies because they often employed different parameters and analytical methods. Three protocols are described here. The first uses maximum intensity projection confocal images to measure the area of acetylcholine receptor (AChR)-rich postsynaptic membrane domains at the endplate and the area of synaptic vesicle staining in the overlying presynaptic nerve terminal. The second protocol compares the relative intensities of immunostaining for synaptic proteins in the postsynaptic membrane. The third protocol uses Fluorescence Resonance Energy Transfer (FRET) to detect changes in the packing of postsynaptic AChRs at the endplate. The protocols have been developed and refined over a series of studies. Factors that influence the quality and consistency of results are discussed and normative data are provided for NMJs in healthy young adult mice.     

The ultrastructure of the individual nerve endings of the tonic fibers in the frog

A regular diminution of specific areas of synaptic contacts and active zones (AZs) along the terminals towards the distal parts has been first shown. The discontinuity was found in the terminal nerve branch apposition to the muscle fiber as a result of periodic intercalation of the Schwann cell and its processes into the synaptic gap. A significant variability in shapes of active zones lengthways the terminal is revealed. It is suggested that all these structural features may reflect the functional properties of synapses on the tonic muscle fibres.     

Ultrastructural demonstration of acetylcholinesterase activity of motor endplates via osmiophilic diazothioethers

Summary The ultrastructural chemical localization of acetylcholinesterase of motor endplates of rat intercostal muscle has been studied with three new esterase substrates. These substrates, although not specific for acetylcholinesterase, have differential affinities for various types of esterases; two of them (NTA and TAB) are hydrolyzed preferentially by acetyl esterase enzymes, and the third (TPB) is a propionic acid ester and is hydrolyzed preferentially by pseudocholinesterase and other esterases. The end-product of the enzymatic reaction is converted to a diazothioether (droplet form) and upon osmication this is converted to a coordination polymer of osmium which has ideal properties for electron microscopy.Although this study supports previous observations that enzymatic activity can be found primarily on the post-synaptic membranes of the motor endplate, no enzymatic activity was noted on the pre-synaptic membrane, within the synaptic cleft, or on the basement membrane unless incubation was prolonged, resulting in overstaining. Neither was enzyme activity seen on membrane-free ribosomes and the ribosome-studded sarcoplasmic reticulum. Axonal vesicles also failed to exhibit enzymatic activity which had been noted with the method using thiolacetic acid and lead. A correlation of esterase activity with ultrastructural localization, using the substrate TPB, suggests that a buffer zone of nonspecific esterase activity is present beneath the subneural apparatus which limits the aberrant, accidental, or abnormal distribution of acetylcholine within a clearly defined area of sarcoplasm in the vicinity of the motor endplate of the muscle fiber.This investigation was supported by research grants from the National Cancer Institute (CA-2078 and CA-02478) and National Institute of Neurological Diseases and Blindness (NB 04096). Acknowledgement for technical assistence is due Miss Julia Silhan.This investigation was carried out during the tenure of a Public Health Service research career program award NB 5820 from the N.I.N.D.B.     

The fine structure of the visual system of lycosa (Araneae: Lycosidae)

Summary The optic lobes of spiders contain a well differentiated synaptic region — the lame medullaire — in which the photoreceptor axon terminals synapse with the axons of the second order neurons.Each photoreceptor terminal has a very irregular outline and contains a great number of vesicles. It sends out collateral branches which end either in contact with other photoreceptor terminals or in contact with second order fibers. The second order fibers lie deeply recessed within folds of the photoreceptor terminal membrane. Frequently branches of the second order fibers can be seen as independent elements within the photoreceptor terminals. The synaptic loci are characterized by the presence of synaptic ribbons surrounded by cumuli of vesicles. These synaptic loci are always located at the intermembrane cleft between adjacent second order fibers.Synaptic structures have been found also within the second order fibers which in such cases appear as pre-synaptic elements in regard to the photoreceptor terminals.Research sponsored by the Air Force Office of Scientific Research, Office of Aerospace Research, United States Air Force, under AFOSR Grant Nr. 618-64.     

Electron microscopic studies of the pressoreceptor fields of the carotid sinus of the dog

Summary In the dog, pressosensitive endings of the sinus nerve extend along the border between the adventitia and media of the carotid sinus wall. The axon endings, containing a great number of mitochondria, can be divided into small (600–2,000 nm) and large (6,000–8,000 nm) end swellings. In the terminal region the pressosensitive fibers are surrounded by ramified and highly structured Schwann terminal cells. The topographic location in relation to elastic and collagenous tissue indicates a functional relation between vascular wall and the activity of receptor tissue. A functional connection between receptors and efferent nerve endings in the immediate surroundings has been discussed in this report. Several axon endings contain variable amounts of glycogen which is regarded as an indication for the inactive metabolic state of the ending. Axonal swellings demonstrate considerable modification in structure, such as loss of structural integrity in mitochondria, the formation of lamellar fields, vesicular irregularities and disintegration of axoplasm, all of which are considered as the morphological expression of wearing out, degeneration and possibly regeneration.This investigation was supported by the Deutsche Forschungsgemeinschaft (SFB 104)Dedicated to Professor W. Bargmann on the occasion of his 70th birthday