Structure and distribution of neuromuscular junctions on slow muscle fibers in the frog

Active zone structure-function relationships at the neuromuscular junction

The impact of presynaptic transmitter release site organization on synaptic function has been a vibrant area of research for synaptic physiologists. Because there is a highly nonlinear relationship between presynaptic calcium influx and subsequent neurotransmitter release at synapses, the organization and density of calcium sources (voltage-gated calcium channels [VGCCs]) relative to calcium sensors located on synaptic vesicles is predicted to play a major role in shaping the dynamics of neurotransmitter release at a synapse. Here we review the history of structure-function studies within transmitter release sites at the neuromuscular junction across three model preparations in an effort to discern the relationship between VGCC organization and synaptic function, and whether that organizational structure imparts evolutionary advantages for each species.

Quantitative distributions of different cholinesterases and inhibition of acetylcholinesterase by metidathion and paraquat in alimentary canal of common carp

1. The cholinesterases play an important role in the innervation of organs. The ratio of solubilized to membrane-bound cholinesterase and the quantitative distributions of acetylcholinesterase and butyrylcholinesterase were measured in different segments of the gut of carp (Cyprinus carpio) connected with different types of nerve-muscle synapses in different parts of the alimentary tract. 2. The inhibition of acetylcholinesterase (EC 3.1.1.7.) by the herbicide paraquat and the insecticide metidathion was measured in different parts of the gut of carp. 3. Metidathion and paraquat significantly decreased the activity of acetylcholinesterase in different segments of the alimentary tract of common carp, in a concentration-dependent manner.

Proximodistal gradients of the postjunctional folds at the frog neuromuscular junction: a scanning electron microscopic study

Frog endplates were studied with the scanning electron microscope following the removal of the presynaptic terminal by collagenase and acid treatments. Endplates had 2-14 branches of primary cleft. The longest branches were parallel to the muscle fiber. Short branches oblique or perpendicular to the muscle fiber were also present near the central region of the endplates. The openings of postjunctional folds in the primary cleft were clearly visible at the bottom of the primary cleft and could be counted and measured. The longest primary cleft branches of each endplate were divided into segments of 20 microns (length corrected for shrinkage). The number of postjunctional folds per micrometer of primary cleft, the average postjunctional fold length (i.e. across the primary cleft) and the total postjunctional fold's length per micrometer of primary cleft were evaluated for each 20-microns segment of primary cleft. Negative proximodistal gradients were observed for these three parameters for the long branches of primary cleft, i.e. values were higher in the proximal region (near the motor axon) than in the distal region. These postsynaptic gradients probably reflect similar or smaller proximodistal presynaptic gradients for the active zones along the nerve.

Acetylcholinesterase in the alimentary canal of fish: light and electron microscopic detection, quantitative distribution in different segments of the gut

The acetylcholinesterase activity was measured and histochemically localized in the alimentary tract of 2 fish species, carp (Cyprinus carpio) and tench (Tinca tinca). A comparison was made of the activities in the different gut segments. Light and electron microscopic histochemistry revealed acetylcholinesterase-positive cell bodies along the entire length of the alimentary canal in both species, between the muscular layers. Acetylcholinesterase-positive, cholinergic motor endplates were frequent in the esophagus of both carp and tench, and they were also present in the striated muscular layers of the tench stomach and midgut. The enzyme activity detected by the method of Ellman et al. (1961) was highest (16.3 U/mg protein) in the tench foregut and midgut, while it was at the same lower level (9.5 U/mg protein) in each segment of the carp gut and in the tench hindgut. The morphological findings and the higher acetylcholinesterase activity in the tench foregut and midgut suggest that the enteric striated musculature is endowed with denser cholinergic innervation than the enteric smooth musculature.

Enteric neuromuscular junctions: comparison of ultrastructural features in different phylogenetic groups

The enteric neuromuscular junctions of snail (Helix pomatia), locust (Locusta migratoria migratorioides), cockroach (Periplaneta americana), carp (Cyprinus carpio) and tench (Tinca tinca) were studied by means of different light and electron microscopic methods. The nitroblue tetrazolium staining revealed that the myenteric plexuses of the above species are composed of nerve cells, a network of varicose nerves and nerve bundles. Instead of highly organized ganglia, single neurons or small groups of 2-4 cells are characteristic of the invertebrates and fish studied. Catecholaminergic fluorescence induced by glyoxylic acid was detected in the muscular layer of the entire alimentary tract in snail and the hindgut of tench. Fluorescent nerves and perikarya were frequent in the snail gut, while only nerves and no perikarya were found in tench. A close contact between enteric muscles and nerves is the most common form of enteric neuromuscular junction in both the smooth (i.e. the molluscan and fish gut) and the striated (i.e. the insect gut) musculature. The striated musculature (i.e. the insect gut, the oesophagus of carp, and the oesophagus, stomach and the midgut of tench) also receives a synaptic input. Cytochemical evidence is provided of the cholinergic character of fish motor endplates. The ultrastructural appearance and vesicle population of certain nerve terminals suggest a universal role of aminergic and peptidergic control in gut motility.

Structural alterations in the membrane of the slow muscle fiber of Rana temporaria after denervation

Mixed fiber bundles as well as separated slow and fast fibers from normal and denervated muscles of Rana temporaria were freeze-fractured. The membranes of both fiber types are distinguished in this species by the presence of fairly regularly distributed particle aggregates or arrays of different shapes and sizes; the number per unit area of the membrane is six times higher in fast than in slow fibers. The intramembrane particle (IMP) density is higher in slow than in fast fibers. After denervation, the fast fiber membrane structure does not change whereas the slow fiber membrane acquires the characteristics of the fast fiber, i.e., an increase in the density of particle arrays and a decrease in IMP density. These changes in the slow fiber membrane are compared to the altered physiological properties of this fiber type after denervation.

Small vesicle bouton synapses on the distal half of the lateral dendrite of the goldfish Mauthner cell: freeze-fracture and thin section study

To understand principles of synaptic integration, it is necessary to define the types of synapses on a particular neuron and their distribution. Thin sectioning and double replica freeze-fracture techniques were employed to characterize the small vesicle bouton (SVB) synapses on the distal half of the Mauthner (M) cell lateral dendrite, which probably mediate a remote dendritic inhibition. Three morphologically distinct SVB synapses, types A, B, and C, were found. These three SVB synapses form roughly 90% of the synapses on the distal half of the lateral dendrite, with types A and B being most common. The SVB A synapse is characterized by mostly oval and round synaptic vesicles, a discrete presynaptic active zone with a highly variable shape, and a postsynaptic active zone with no apparent particle aggregate in either the E or P face. At the SVB B synapse, most of the synaptic vesicles are flat. A very high particle density is present throughout the presynaptic P face, and vesicle attachment sites are dispersed over much of the presynaptic membrane. Postsynaptic P face particle aggregates are subjacent to the presynaptic vesicle attachment sites, and are often large and anastomosing. The SVB C synapse is characterized by synaptic vesicle profiles that vary from flattened to round. The SVB C cytoplasm was unclouded by the flocculent material that characterized SVBs A and B. The presynaptic active zones at the SVB C synapse are discrete, and macular or oblong. No particle aggregates are apparent in the postsynaptic active zone. Small, macular particle aggregates were found in nonactive zone regions of the postsynaptic E face of all three types of SVBs. Small subsurface cisterns were also observed underlying the M cell membrane at all three types of SVB synapses. Neither the postsynaptic E face aggregates nor the subsurface cisterns were ever observed directly subjacent to presynaptic active zones, but were often seen adjacent to active zones. Short, straight rows of particles and short cylinders were often seen in both pre- and postsynaptic surrounding zone regions of SVB A and C synapses. These structures are thought to represent tight junctions.

Changes in the dimensions of release sites along terminal branches at amphibian neuromuscular synapses

The probability of transmitter secretion from release sites declines along the length of most long terminal branches (greater than 78 micron) at toad (Bufo marinus) neuromuscular junctions; in contrast, few short terminal branches (less than 78 micron) show such a decline. The present study was carried out to see if any of the dimensions of release sites change along the length of terminal branches in a way that can be correlated with the decrease in secretion probability. The size of presynaptic release site structures was determined by examining serial transverse sections through entire terminal branches with the transmission electron microscope; the size of postsynaptic release site structures was determined by examining terminal gutters with the scanning electron microscope after the removal of terminal branches. Long terminal branches showed a significant decrease in the length of their synaptic contact and cross-sectional area (terminal size) with distance from the origin of the branch. In contrast, there was no significant difference in the length of close apposition (less than 0.2 micron) between the nerve terminal and postsynaptic muscle membrane; furthermore, neither the length of postsynaptic folds nor the frequency of the folds along the length of the terminal gutter changed. Short terminal branches showed no significant differences in the dimensions of either presynaptic or postsynaptic release site structures. The decline in the length of synaptic contacts whilst the length of close apposition remains relatively constant is due to the progressive encroachment of Schwann cell processes between presynaptic and postsynaptic membranes along the length of long terminal branches.

Characteristics of synaptic currents in frog muscle fibers of different types

A study was made of synaptic currents in voltage-clamped muscle fibers of the frog. Fast, submaxillaris, and slow muscle fibers are innervated by nerve fibers of different conduction velocities. To avoid spatial complications, transmitter release by nerve impulses was restricted to the site of recording and reduced to single quanta (unitary endplate currents: uepc). Following nerve stimulation, the time course of transmitter release was longer and more variable in slow and submaxillaris muscle fibers than in the fast fibers. The time constant of decay of uepc in submaxillaris and slow fibers was, respectively, about 1.8 and 2.9 times slower than the decay of uepc in fast fibers. This is due mainly to differences in the lifetime of the channels opened by acetylcholine. The neuromuscular junctions in submaxillaris muscle fibers are bouton-like or longer branched contacts; and the unitary currents in the bouton junctions have a slower time course. It is concluded that the synaptic membrane in the different types of muscle fibers has synaptic acetylcholine-operated channels that have different kinetic properties, and that these properties are determined by the type of axon that innervates the muscle fiber.

The probability of quantal secretion along visualized terminal branches at amphibian (Bufo marinus) neuromuscular synapses

The number of quanta secreted from selected sites along terminal branches at toad (Bufo marinus) neuromuscular junctions was determined. Terminal branches were visualized by prior staining with the fluorescent dye, 3-3 Diethyloxadicarbocyanine iodide (DiOC2(5)); neither impulse conduction nor quantal release were affected by DiOC2(5) at concentrations less than 10 microM. The evoked quantal release recorded with an extracellular micro-electrode (me) at different sites along the length of terminal branches was determined in an external calcium concentration, [Ca]o, of 0.35-0.45 mM. For short branches (40-80 microns), me remained approximately constant for over 60% of the branches; for the rest, me declined approximately exponentially with an average length constant of 17 +/- 2 microns (mean +/- S.E. of mean). For both medium (81-120 microns) and long branches (121-160 microns), me declined in nearly all cases approximately exponentially with length constants of 39 +/- 5 and 54 +/- 8 microns respectively. These changes in me were observed at synapses having a wide range of terminal branching patterns. Some DiOC2(5)-stained branches possessed discontinuous cholinesterase staining. In general, me declined along these branches in the same way as along DiOC2(5)-stained branches with continuous cholinesterase staining. It is suggested that because of the decline in me along most medium and long terminal branches, many release sites have a very low probability for secretion in low [Ca]o. Release sites near the point of nerve entry, which have a relatively high probability, therefore make the main contribution to secretion recorded with an intracellular micro-electrode. As a consequence, transmitter secretion from the whole terminal does not fluctuate from impulse to impulse as much as expected if there were a large number of release sites, each with a low probability of secretion. Transmitter secretion then follows binomial rather than Poisson statistics.

Differences in synaptic efficacy at neuromuscular junctions in frog twitch muscles

A comparison was made of neuromuscular junctions in cutaneous pectoris and cutaneous dorsi muscles of Rana pipiens in order to study mechanisms controlling synaptic efficacy. Other than a small difference in junctional size, the two muscles were structurally and functionally very similar. Despite these similarities, cutaneous pectoris junctions had substantially higher synaptic safety margins. With intracellular recording, it was apparent that the difference in safety margin was due to a large difference in transmitter release. In low-Ca2+ solutions, levels of evoked and spontaneous release were 4 times higher in the cutaneous pectoris. When corrected for differences in nerve terminal size at identified junctions, there remained a 3-fold difference in evoked release and a 6-fold difference in spontaneous release per unit terminal length. Differences in normal Ringer solution were 1.8- and 2.5-fold for evoked and spontaneous release, respectively. There was no simple relationship between synaptic efficacy and the total amount of nerve terminal supported by each motoneurone in different frog muscles. We concluded that there can be large differences in synaptic efficacy without correlated structural differences visible with the light microscope.

A comparison of active zone structure in frog neuromuscular junctions from two fast muscles with different synaptic efficacy

To search for ultrastructural correlates of differences in synaptic safety factor and neurotransmitter release, neuromuscular junctions from the cutaneous pectoris and cutaneous dorsi muscles of the grass frog Rana pipiens were freeze fractured. Synaptic efficacy in these muscles was determined by the extent to which isometric twitch tension could be blocked by lowering [Ca2+] in the bathing solution. We found that junctions in the cutaneous pectoris were significantly more effective than those of the cutaneous dorsi. Morphometric analysis of 16 junctions from each type of muscle showed significant differences in some aspects of active zone structure. Cutaneous pectoris terminals had longer active zone segments and active zones spaced more closely together. This resulted in 20% more active zone length per unit terminal length in the cutaneous pectoris. Cutaneous dorsi terminals had active zones that were more often segmented into two or more sections at a single junctional fold. Mean active zone length per junctional fold and the number of active zone particles per micrometre of active zone length were not significantly different. As a result of the somewhat larger terminal width in the cutaneous dorsi, the percentage of terminal width occupied by active zone was greater in the cutaneous pectoris. As an attempt to indirectly estimate active zone spacing with the light microscope, we applied rhodamine-conjugated alpha bungarotoxin to neuromuscular junctions from the cutaneous pectoris and cutaneous dorsi. No significant difference in the spacing of fluorescently labelled acetylcholine receptor bands was found between the two types of junctions. Our results indicated that the greater active zone length per unit terminal length in the cutaneous pectoris was associated with its increased synaptic efficacy. In addition the continuity and particle organization of active zones may have contributed to the observed differences in synaptic safety factor at frog neuromuscular junctions.

An ultrastructural comparison of neuromuscular junctions in normal and developmentally arrested Rana pipiens larvae: limited maturation in the absence of metamorphosis

Neuromuscular junctions in the rectus abdominis muscles of normal and developmentally arrested Rana pipiens larvae were studied with freeze fracture and conventional electron microscopy to determine whether structural aspects of junctional maturation depend on metamorphosis. Comparison was made between junctions in premetamorphic larvae 1-3 months old and junctions in larvae that had remained in premetamorphosis for more than a year (more than four times as long as normal). In most respects, junctions from the two groups of larvae were similar. Unlike adult junctions, nerve-muscle contacts in both larval groups were pleomorphic and often involved more than one neuronal process; Schwann cell processes very rarely extended between nerve and muscle. Active zone structure ranged from total disorganization to an adult pattern of highly ordered double rows of particles aligned over junctional folds. Only quantitative analysis revealed differences between junctions in old and young larvae. The older larvae had fewer nerve-muscle contact sites involving multiple neuronal elements and a higher ratio of active zone length to presynaptic membrane area, although the mean active zone length was the same in the two groups. The results indicate that the maturation of junctional shape, the branching pattern of the axons, and the relationship of presynaptic axons to Schwann cells must be directly or indirectly dependent on the hormonal or behavioral changes associated with metamorphosis.

Ultrastructural correlates of experimentally altered transmitter release efficacy in frog motor nerve terminals

After experimentally inducing long term changes in transmitter release, a series of frog neuromuscular junctions were studied with intracellular recording and then semi-serially sectioned and examined in the electron microscope. Transmitter release per unit length of motor nerve terminal was well correlated with several measures of the length of individual presynaptic active zones and with the number of mitochondria per terminal. Total release from each terminal correlated with estimates of the total amount of active zone. This study of neuromuscular junctions in sartorius muscles of the frog Rana pipiens was undertaken to search for ultrastructural correlates of the increase in transmitter release efficacy that follows denervation of the contralateral sartorius. This treatment typically results in greatly enhanced release at some synapses while others appear unaffected. In the present study, nine identified junctions with known physiological properties were sectioned every 6 micron throughout much of their length to yield 40-105 cross-sectional profiles per junction. Overall, these 9 synapses showed a 33-fold range in quantal transmitter release and an 18-fold range in release per unit nerve terminal. Release correlated with estimates of active zone size. No correlations were found between release and the density of synaptic vesicles adjacent to active zones. Our results suggest that active zones in motor nerve terminals are plastic structures, and that changes in active zone size may be the structural basis of long term changes in transmitter release and synaptic efficacy.

Ultrastructural correlates of naturally occurring differences in transmitter release efficacy in frog motor nerve terminals

Motor nerve terminals in cutaneous pectoris muscles of the frog Rana pipiens release more transmitter and form synapses with higher levels of effectiveness than do those in sartorius muscles. Neuromuscular junctions from these two muscles were compared in the electron microscope to search for ultrastructural correlates of differences in transmitter release and synaptic effectiveness. The following measurements were made from cross-sections of junctions with known levels of effectiveness: (a) the presence of active zones, the presumed sites of transmitter release, (b) active zone size, (c) the perimeter, cross-sectional area, height and width of nerve terminals, (d) number of mitochondria, (e) vesicle density, and (f) the extent to which Schwann cells wrap terminals. Nerve terminals in the two muscles did not differ in size, shape or vesicle density. The more strongly releasing cutaneous pectoris terminals did, however, have significantly larger active zones due to deeper invagination of the terminal into the postsynaptic gutter and lesser interposition of Schwann cell processes between presynaptic and postsynaptic membranes. Cutaneous pectoris terminals also contained more mitochondria, presumably to supply the greater energy demand imposed by high release levels.

Innervation and membrane specialization at neuromuscular junctions in submaxillaris muscle of the frog

The submaxillaris muscle of the frog after zinc iodide-osmium staining reveals the presence of polyneural innervation. Cholinesterase staining shows that the longer terminals have postsynaptic folds whereas the smaller terminals (up to 5 micron) lack them. Thin-section electron microscopy shows that muscle fibers with or without an M line have terminals with and without postsynaptic folds. The terminals with postsynaptic folds have presynaptic membrane outpocketings above folds. These outpocketings are rudimentary or absent in the terminals without postsynaptic folds. In longer junctions, the P face of the presynaptic membrane has double rows of paired particles on active zone ridges perpendicular to the axis of the muscle. In smaller junctions active zone ridges are rudimentary or absent and double rows of particles form various patterns. Postsynaptic active zones in longer junctions consist of clusters of particles leaving gaps in between, whereas in the smaller junctions they lack gaps. The polyneural innervation and different deployment of membrane particles at neuromuscluar junctions could be a factor responsible for different physiological properties of this muscle.