Regulated spacing of synapses and presynaptic active zones at larval neuromuscular junctions in different genotypes of the flies Drosophila and Sarcophaga

Synapses at larval neuromuscular junctions of the flies Drosophila melanogaster and Sarcophaga bullata are not distributed randomly. They have been studied in serial electron micrographs of two identified axons (axons 1 and 2) that innervate ventral longitudinal muscles 6 and 7 of the larval body wall. The following fly larvae were examined: axon 1--wild-type Sarcophaga and Drosophila and Drosophila mutants dunce(m14) and fasII(e76), a hypomorphic allele of the fasciclin II gene; and axon 2--drosophila wild-type, dunce(m14), and fasII(e76). These lines were selected to provide a wide range of nerve terminal phenotypes in which to study the distribution and spacing of synapses. Each terminal varicosity is applied closely to the underlying subsynaptic reticulum of the muscle fiber and has 15-40 synapses. Each synapse usually bears one or more active zones, characterized by dense bodies that are T-shaped in cross section; they are located at the presumed sites of transmitter release. The distribution of synapses was characterized from the center-to-center distance of each synapse to its nearest neighbor. The mean spacing between nearest-neighbor pairs ranged from 0.84 microm to 1.05 microm for axon 1, showing no significant difference regardless of genotype. The corresponding values for axon 2, 0.58 microm to 0.75 microm, were also statistically indistinguishable from one another in terminals of different genotype but differed significantly from the values for axon 1. Thus, the functional class of the axon provides a clear prediction of the spacing of its synapses, suggesting that spacing may be determined by the functional properties of transmission at the two types of terminals. Individual dense bodies were situated mostly at least 0.4 microm away from one another, suggesting that an interaction between neighboring active zones could prevent their final positions from being located more closely.

Synaptic structure and transmitter release in crustacean phasic and tonic motor neurons

The paired phasic and tonic motor neurons supplying the extensor muscle in the crayfish leg were investigated to establish whether differences in synaptic structure could account for large differences in transmitter release at the neuromuscular junctions. Nerve terminals with transmitter release that had been assessed from recordings made with a focal "macro-patch" electrode were subsequently labeled, processed for electron microscopy, and reconstructed from serial sections. At a frequency of 1 Hz, quantal contents of phasic terminals were 90-1300 times greater than those of tonic terminals when both were recorded at the same location. At higher frequencies, facilitation was pronounced at tonic, but not phasic, terminals. Reconstructions of recording sites showed that both phasic and tonic terminals possessed many small synapses, usually with one or more structurally defined active zones. Mean synaptic contact area was larger for tonic terminals, and the number of individual synapses per length of nerve terminal was also larger. Active zones were not different in size for the two terminals. At low frequencies, quantal emission per synapse is much greater for phasic terminals. The higher quantal content of phasic terminals and their synapses cannot reasonably be accounted for by more or larger synapses or active zones at the recording sites. Because structural features alone are not likely to produce the very large differences in quantal content of phasic and tonic terminals observed at low stimulation frequencies, it is likely that other properties of the nerve terminal are largely responsible for these differences.

Muscle fibers in regenerating crayfish motor nerves

Single discrete muscle fibers were found in regenerating motor nerves in adult crayfish. The regenerating nerves were from native or transplanted ganglia in the third abdominal segments and consisted of several motor axons. The proximal end of these motor axons showed numerous sprouts. Muscle fibers in these regenerating nerves appeared newly developed and were innervated by excitatory nerve terminals. A likely source of these novel muscle fibers may be blood cells in the nerve or satellite cells from neighboring muscle. Contacts made by axon sprouts with other axon sprouts, glia, and muscle fiber, in the form of a dense bar with clustered clear vesicles, characterized the regenerating nerve. These contacts may provide a possible signaling pathway for axon regeneration and myogenesis.

Claw Transformation and Regeneration in Adult Snapping Shrimp: Test of the Inhibition Hypothesis for Maintaining Bilateral Asymmetry

In the paired asymmetric claws of adult snapping shrimp, Alpheus heterochelis, the minor, or pincer, claw may transform into a major, or snapper, claw if the existing snapper claw is damaged or lost, implying that an intact snapper claw normally inhibits the contralateral pincer claw from advancing to a snapper. We find that the pincer-to-snapper advancement in external form occurs almost immediately after the snapper is lost even as late as the premolt stage. The transforming claw in turn inhibits the newly regenerating pincer claw from becoming a snapper, but if the dactyl of the transforming claw is cut, then snapper-based inhibition is removed and the contralateral claw may regenerate as a snapper, resulting in shrimp with paired snapper claws. However, damaging an established snapper claw will not allow another snapper claw to regenerate at the pincer site, implying that less inhibition is required to restrict a newly regenerating claw to a pincer than to arrest an existing pincer claw. Inhibition may be manifested largely in terms of quantity of innervation. Hence the greater innervation of the snapper side over the pincer side would inhibit the pincer side, accounting for the regeneration of paired claws in their previous configuration following loss of both claws. Loss of the paired claws in two consecutive molts retards their development so that both claws often appear as pincers, but in succeeding molts one usually differentiates into a snapper and bilateral asymmetry is restored. In contrast, shrimp with paired snapper claws retain this configuration over several molts unless one or both of the claws are lost; in that case, regeneration restores bilateral asymmetry. Thus, bilateral asymmetry of the paired claws of adult shrimp is governed by a strong intrinsic lateralizing mechanism in which the snapper claw inhibits the pincer from advancing to another snapper.

Morphological correlates of neural regeneration in the feeding system of Aplysia californica after central nervous system lesions

Morphological techniques were used to study regeneration of central neural pathways involved in feeding behavior following bilateral crushes of the cerebral-buccal connectives (CBCs). Electron microscopic analysis revealed that CBC crushes completely transect axons within the nerve core while leaving a remnant of the nerve sheath intact. Changes in the ultrastructure of the CBCs at the crush site were determined for 1, 7, 14, 21, and 50 days postlesion. At 1 day postlesion, the crush site was no longer compressed, and the nerve core had assumed a circular shape. In addition, several small axon profiles were evident, and large areas of tissue debris and prominent microglial cells were observed. Membranous debris and hemocytes were also present in sinuses that appeared in the sheath adjacent to the crush site. From 7 to 50 days postlesion, the core of the nerve at the crush site increased in size due to the addition of small diameter axons. Initially, the sheath surrounding the crush site exhibited hyperplasia and contained a few small bundles of processes, apparently due to newly sprouted axons that had strayed from the nerve core. By 50 days postlesion, the crush site appeared nearly normal; the nerve core was reacquiring the normal radial pattern of axon profiles with some medium-sized axon profiles covered with glial sheath and exhibiting invaginations typical of the intact CBC. However, there was still a distinct lack of large diameter axons. Cobalt backfills across the crush site revealed neurons in the cerebral ganglion by postlesion day 9. Positions of stained cell bodies were consistent with those observed in controls, although the numbers of stained neurons did not recover to control levels even by postlesion day 63. The changes in the crush site and return of cell body staining with time postlesion are correlated with the recovery of consummatory feeding.

Synaptic exocytosis of dense-core vesicles in blue crab (Callinectes sapidus) stomach muscles

Neuromuscular terminals of a single motoneuron to four muscles (CPV7a, GM5a, CV2, and CV3) in the stomach of the blue crab Callinectes sapidus showed structural evidence for the exocytotic release of dense-core vesicles exclusively at synapses. The primary evidence was the appearance of dense cores in the synaptic cleft, accompanied by indentations of the presynaptic or postsynaptic membrane. In their simplest form, these consisted of an omega-shaped figure of the presynaptic membrane enclosing one dense core, denoting release of a single dense-core vesicle. A larger indentation of the presynaptic membrane enclosing several dense cores denoted multiple release. A more complex form of multiple release was where the presynaptic membrane was normal, but the postsynaptic membrane elaborated into a sac projecting into the granular sarcoplasm and filled with dense cores. The postsynaptic sac in some instances was compressed into a thin, fingerlike extension, which lacked dense cores and, at its distal end, separated into small cisternae, suggesting a mechanism for membrane recycling. Profiles depicting single and multiple releases of dense-core vesicles were found more frequently at neuromuscular terminals that release relatively large amounts of transmitter with a single stimulus, such as CV2 and CV3, compared to those releasing smaller amounts, such as CPV7a and GM5a. The disparity in release sites among the four muscles of this single motor unit and the fact that many of the multiple-release figures were closely adjacent to the active zones for transmitter release suggest a possible modulatory role for dense-core vesicles in synaptic transmission. Such modulation may be long lasting, as implied by the postsynaptic sacs, which may permit prolonged release of the contents of their dense cores into the synaptic cleft. This is in keeping with the functional role of these stomach muscles, which is to be continuously active for long periods of time.

Structural-functional differences of a crab motoneuron to four stomach muscles

A motor unit in the stomach of the blue crab, Callinectes sapidus, consists of four separate muscles involved in different aspects of the trituration and filtering of food. Motor nerve terminals to two of the muscles (CPV7a and GM5) release small amounts of transmitter (low-output) while those to the other two muscles (CV2 and CV3) release between three and five-fold greater amounts (high-output). Structural features underlying the disparity in synaptic strength were analysed with thin serial-section electron microscopy. Nerve terminals were similar in their volume percent of mitochondria, clear vesicles and dense core vesicles among the four muscles. This was also the case for the number and size of synaptic contacts. However, presynaptic dense bars representing active zones were longer and occurred more frequently at high-output synapses than at low-output ones. High-output synapses were also characterized by the close spacing of adjacent dense bars. The longer and more closely spaced dense bars at high-output synapses would be factors in the generation of larger synaptic potentials in these terminals compared to their low-output counterparts. Other factors, however, need to be considered to fully account for the physiological differences in synaptic strength among the four muscles.

Sexually dimorphic patterns of neural organization in the feeding appendages of fiddler crabs

The organization of sensory nerves and sensilla was examined in the feeding claw of two species of fiddler crabs, Uca pugnax and U. pugilator, using neuroanatomical and behavioral techniques. Surveys of the populations of axons indicate that claws of adult crabs contain 25000-40000 neurons. Approximately 85% of the population consists of axons with diameters less than 1 microm, suggesting they may represent chemosensory neurons. Females show an enhanced population of these small (putative chemosensory) axons relative to males, providing a mechanism to explain previously observed sexual differences in behavioral chemosensitivity to feeding stimulants. Surveys of the claw surface show a variety of external structures that could contain either chemo- or mechanosensory receptor neurons. There are hair-like sensilla of several types, some of which are more abundant in females than in males. In addition, claws show previously undescribed pit sensilla reminiscent of known bimodal chemo- and mechanosensory sensilla found in certain decapod crustaceans. Morphological properties of hair-like sensilla, as well as their small number in relation to the large population of presumptive chemosensory axons, suggest that they have a limited role in chemosensation. Most of the chemosensory axons probably originate in the pit sensilla.

Structural features of crayfish phasic and tonic neuromuscular terminals

We examined the fine structure of terminals of the phasic and tonic excitatory axon to the crayfish limb extensor muscle. The phasic terminals are known to release 50-100 times more transmitter for a small length of terminal for a single impulse. Phasic terminals labeled with horseradish peroxidase (HRP) were relatively thin and contained a single unbranched mitochondrion; tonic terminals were much thicker, and their varicosities contained several multibranched mitochondria. Tonic terminals devoted a larger proportion of their total volume to mitochondria. The percentage volume of clear synaptic vesicles was slightly higher in phasic axon terminals, but as the tonic axon terminals were fivefold larger in volume, the total synaptic volume is much greater in tonic than phasic terminals. The number of synapses per length of terminal, and the total number of active zones per length of terminal, were greater for tonic terminals, and individual synapses were, on average, slightly larger in surface contact area for tonic terminals. In contrast, individual active zones were, on average, longer in phasic synapses. A higher proportion (50%) of phasic synapses had multiple active zones than was the case for tonic synapses (16%), and pairs of closely spaced active zones were more frequently found on phasic synapses. These findings clearly rule out synapse and active zone number as a factor contributing to higher transmitter output, but suggest that active zone size and synaptic complexity, as evidenced by multiple closely spaced active zones in a single synapse, are likely to play a causal role in the greater transmitter release of the phasic terminal. Even synapse complexity would not be enough to account fully for the large difference in terminal transmitter output, and additional factors may include electrical and biochemical differences.

Structure of allotransplanted ganglia and regenerated neuromuscular connections in crayfish

In adult crayfish, Procambarus clarkii, motoneurons to a denervated abdominal superficial flexor muscle regenerate long-lasting and highly specific synaptic connections as seen from recordings of excitatory postsynaptic potentials, even when they arise from the ganglion of another crayfish. To confirm the morphological origins of these physiological connections we examined the fine structure of the allotransplanted tissue that consisted of the third abdominal ganglion and the nerve to the superficial flexor muscle (the fourth ganglion and the connecting ventral nerve cord were also included). Although there is considerable degeneration, the allotransplanted ganglia display intact areas of axon tracts, neuropil, and somata. Thus in both short (6-8 weeks) and long (24-30 weeks) term transplants approximately 20 healthy somata are present and this is more than the five axons regenerated to the host muscle. The principal neurite and dendrites of these somata receive both excitatory and inhibitory synaptic inputs, and these types of synaptic contacts also occur among the dendritic profiles of the neuropil. Axon tracts in the allotransplanted ganglia and ventral nerve cord consist largely of small diameter axons; most of the large axons including the medial and lateral giant axons are lost. The transplanted ganglia have many blood vessels and blood lacunae ensuring long-term survival. The transplanted superficial flexor nerve regenerates from the ventral to the dorsal surface of the muscle where it has five axons, each consisting of many profiles rather than a single profile. This indicates sprouting of the individual axons and accounts for the enlarged size of the regenerated nerve. The regenerated axons give rise to normal-looking synaptic terminals with well-defined synaptic contacts and presynaptic dense bars or active zones. Some of these synaptic terminals lie in close proximity to degenerating terminals, suggesting that they may inhabit old sites and in this way ensure target specificity. The presence of intact somata, neuropil, and axon tracts are factors that would contribute to the spontaneous firing of the transplanted motoneurons.

Synaptic structural complexity as a factor enhancing probability of calcium-mediated transmitter release

1. In a model synaptic system, the excitatory neuromuscular junction of the freshwater crayfish, the nerve terminals possess synapses that vary in structural complexity, with numbers of active zones ranging from zero to five. Active zones on individual synapses show a wide range of separation distances. We tested the hypothesis that two active zones of a single synapse in close proximity can enhance the localized increase in free calcium ion concentration, thus enhancing the probability of neurotransmission at that synapse. We evaluated the increase in calcium ion concentration as a function of distance between adjacent active zones. 2. To test this hypothesis, a reaction-diffusion model for Ca2+ entering the presynaptic terminals was used. This test was used because 1) present measurement techniques are inadequate to resolve quantitatively the highly localized, transient calcium microdomains at synaptic active zones; and 2) there is presently no suitable preparation for physiological recording from isolated synapses with varying distances between active zones. Included in the model were intracellular buffer and a typical distribution of voltage-activated Ca2+ channels for an active zone, estimated from freeze-fracture micrographs. 3. The model indicated that localized Ca2+ clouds from discrete active zones can overlap to create spatial enhancement of Ca2+ concentration. The degree of interaction between two active zones depends on the distance between them. When two typical active zones are separated by < or = 200 nm, the maximum intracellular Ca2+ concentration ([Ca2+]i) is greater at 1) the midpoint between them, and 2) the center of each one, than at the corresponding positions for a single isolated active zone. Enhanced [Ca2+]i at the edge of the active zone where "docked" synaptic vesicles occur would be expected to have an effect on transmitter release. 4. When the model includes no intracellular buffer, the increase in [Ca2+]i is a linear function of calcium channel current, but is a nonlinear function of the number of conducting calcium channels in an active zone. With immobile buffer included, the increase in [Ca2+]i is nonlinear with respect to both channel current and number of conducting channels. 5. Inclusion of immobile buffer in the model provides "released" residual calcium that slowly accumulates during a train of current pulses. Released residual calcium accumulates more rapidly at paired active zones separated by < or = 200 nm that at single isolated active zones. 6. We propose that the probability of release is enhanced at synapses with closely associated active zones. Synapses of this type ("complex" synapses) could be selectively recruited when the neuron is active at low frequencies. At higher frequencies of neuronal activity, more distant active zones may interact and acquire a greater probability of releasing quanta. This would provide the nerve terminal with one component of a mechanism for frequency facilitation, because the number of quanta released by the terminal as a whole would increase with frequency. Thus variation in synaptic complexity in a nerve terminal provides a mechanism for short-term plasticity of transmitter release.

Neural factors influence the degeneration of muscle fibers in the chelae of snapping shrimps

The asymmetric pincer and snapper claws in the snapping shrimp differ in external morphology and musculature. The snapper is a massive claw used for displays and defense; the pincer is small and slender, used for feeding and burrowing. The snapper has only slow muscle fibers; the pincer has both slow and fast. Removal or denervation of the snapper claw induces transformation of the contralateral pincer to a snapper type of claw at the subsequent molt. A removed claw regenerates as a pincer type, as long as the innervation of the remaining claw is intact. Fast muscle fibers, found exclusively in the pincer claw, normally degenerate completely within 10 d after the moult, which transforms the pincer to a snapper. Morphological transformation of the pincer following removal of the snapper claw can occur even if the pincer claw is denervated. Denervation of the pincer, however, delays degeneration of the fast fibers, increasing the estimated half-time of muscle degeneration, for 4.4 +/- 0.2 to 19.5 +/- 0.8. d after the transforming moult. Neural influences therefore are involved both in the determination of the morphology of the claw and in the induction of degenerative changes during the remodeling of an existing claw.

Inhibitory axoaxonal and neuromuscular synapses in the crayfish opener muscle: membrane definition and ultrastructure

The specific inhibitory motoneuron to the crayfish (Procambarus clarkii) opener muscle provides neuromuscular synapses to the muscle fibers and axoaxonal synapses to the excitatory motor nerve terminals. Freeze fracture of the membrane in both types of synapses show that the presynaptic active zone consists of clusters of large particles (putative calcium channels), which are often encircled by large depressions representing fused synaptic vesicles on the internal leaflet or P face of the presynaptic membrane. Corresponding pits and protrusions mark the external leaflet or E face of the presynaptic membrane. The postsynaptic receptor-bearing surface, characterized for neuromuscular synapses only, consists of rows of particles on both leaflets of the muscle membrane. The organization differs from that seen at excitatory synapses where particles occur only on the E-face leaflet. Serial thin sections of nerve terminals reveal that neuromuscular synapses are significantly larger in proximal fibers than in their central counterparts and support a greater number of presynaptic dense bars (active zones). Axoaxonal synapses also show regional differences; almost three times as many occur in the proximal region compared with the central region. Most synapses possess a single dense bar. The majority of synapses formed by the inhibitory axon are neuromuscular; a minority are axoaxonal. The latter occur in various locations along the excitatory nerve terminals as well as on branches of the axon itself. This preterminal or "off-shore" location could act to cut off entire populations of excitatory synapses or reduce the amplitude of the preterminal action potential.

Neuromuscular regeneration by buccal motoneuron B15 after peripheral nerve crush in Aplysia californica

1. We studied regeneration of neuromuscular connections by identified buccal motoneuron B15 after axotomy produced by crushing nerve 4; the intact contralateral nerve 4 served as control. Electrophysiological recordings, intracellular dye injections, and light and electron microscopy were used to characterize the nature and time course of neuromuscular reinnervation as well as the fate of the isolated distal stump of the motor axon. 2. Axonal outgrowth or sprouting in the form of numerous "regenerites" occurred from the proximal stump of the transected B15 axon, and these regenerites projected through the crush site along the length of the nerve to innervate target muscles at the periphery. 3. Reinnervation of one of the target muscles, the accessory radula closer (I5), was first detected 3 wk after nerve crush. Neuromuscular excitatory postsynaptic potentials measured in individual I5 muscle fibers were initially small and approached control amplitudes by 8 wk postlesion. Newly regenerated neuromuscular synapses displayed facilitation and depression to repeated B15 stimulation with properties similar to those of control synapses, even at early times postlesion. 4. Reinnervation of other buccal muscles by B15, such as I4, appeared slightly delayed relative to that observed for I5. No evidence of abnormal or enlarged fields of innervation were observed, and as in control preparations, regenerated neuromuscular connections were strictly limited to muscles ipsilateral to the B15 cell body. 5. Physiological evidence suggested that the distal axon stumps of B15, although isolated from their cell bodies, survive for several weeks after axotomy. In addition, several large axon profiles indicative of motor axons were seen in cross-sections of nerve 4 taken close to the muscle and distal to the crush site, indicating survival of distal axon stumps. 6. When B15 was selectively stimulated, the newly formed regenerites failed to fire the distal axon stump of B15, demonstrating that the regenerites do not reinnervate the distal stump. 7. Degeneration of axons in nerve 4 distal to the crush site was observed in cross-sections of the nerve at 8 wk postlesion; using ultrathin sections we found cellular debris in individual axon profiles as well as large acellular masses within nerve 4, the latter likely representing the concretion of many axons. Additional evidence for such degenerative changes appeared in the form of autofluorescing spherical bodies or "spheroids" both in individual axons and the nerve distal to the crush site.(ABSTRACT TRUNCATED AT 400 WORDS)

Muscle and Nerve Terminal Fine Structure of a Primitive Crustacean, the Cephalocarid Hutchinsoniella macracantha

Abdominal muscles of the cephalocarid Hutchinsoniella macracantha resemble the striated muscle fibers of other crustaceans, having regularly aligned sarcomeres that average 5 μm in length; thick, wavy Z-lines; and orbits of eight thin filaments surrounding a thick filament. However, unlike most crustacean muscle fibers, the cephalocarid muscle fibers are not subdivided into myofibrils by elaboration of the longitudinally oriented sarcoplasmic reticulum. Consequently, elements of the transverse tubule and sarcoplasmic reticulum in the form of triads occur scattered over the entire fiber. Motor innervation is by means of scattered nerve terminals, populated with round synaptic vesicles, indicative of excitatory axons. By lacking myofibrils, the cephalocarid and ostracod muscle represents a much simpler condition than the myofibril-rich muscles of the other crustacean classes and signifies a primitive condition in its resemblance to the onycophoran muscle.

Regenerate Limb Bud Sufficient for Claw Reversal in Adult Snapping Shrimps

The paired, bilaterally asymmetric snapper and pincer claws in the adult snapping shrimp Alpheus heterochelis were simultaneously autotomized at the beginning of an intermolt, and the resulting growth of the limb buds was characterized into several stages. At the next molt the limb buds emerged as newly regenerated claws of the same morphotype as their predecessors. Next, the paired claws were autotomized sequentially, with the second autotomy timed to different stages of limb bud growth at the first autotomy site. When the snapper is autotomized and a limb bud varying from stages 1 to 5 is allowed to develop at this site before the pincer is removed, the paired claws regenerate in their previous configuration. Similarly, claw asymmetry is retained when the pincer claw is removed first and an early limb bud (stage 1-2) is allowed to form at this site before the snapper is autotomized. However, claw asymmetry is reversed if an advanced limb bud (stage 3-5) is allowed to form at the pincer site before the snapper claw is removed. Under these conditions a snapper regenerates at the pincer site and a pincer at the snapper site. Because the limb bud at this pincer site regenerates as a snapper rather than a pincer, claw transformation has occurred, with the stage 3-5 limb bud substituting for an intact pincer. Therefore, the minimal requirement for pincer-to-snapper transformation is a stage 3-5 limb bud. We postulate that the newly transforming snapper claw restricts regeneration at the contralateral old snapper site to a pincer, thereby ensuring that claw bilateral asymmetry is present, albeit reversed.

"Strong" and "weak" synaptic differentiation in the crayfish opener muscle: structural correlates

The single excitor motoneuron to the limb opener muscle in the crayfish Procambarus clarkii provides multiterminal innervation to individual muscle fibers. At low impulse frequencies, these neuromuscular synapses generate a threefold larger junctional potential in fibers of the proximal region of the muscle compared to those in the central region. Focal extracellular recording from synapse-bearing "boutons" showed more quantal release at low frequencies in the proximal region. Structural correlates for the physiological differences were sought. Fluorescence microscopy of surface innervation stained with a vital fluorescent dye, 4-Di-2-Asp, showed that density of innervation was not greater in the proximal region and thus could not account for the overall differences in synaptic strength. Freeze fracture studies showed that the intramembrane organization of excitatory synapses and their active zones was qualitatively similar in proximal and central sites. Serial section electron microscopy of several innervation sites in proximal and central regions showed homogeneity in number and size of synapses. However, presynaptic dense bars (at release sites, or active zones) were longer and occurred at a higher density in proximal than in central synapses. The differences in number and length of presynaptic dense bars correlate positively with the differences in synaptic strength represented by junctional potential amplitudes and quantal contents of individual surface recording sites. Since many individual proximal synapses have multiple dense bars, co-operativity among these may serve to enhance transmitter output. It is concluded that occurrence of dense bars is a significant presynaptic correlate of synaptic strength in this neuron.

Two structural adaptations for regulating transmitter release at lobster neuromuscular synapses

The distal accessory flexor muscle (DAFM) in the lobster (Homarus americanus) walking leg consists of 5 muscle fiber bundles. All five bundles, one proximal, one distal, and 3 medial, are innervated by one excitatory and one inhibitory motor neuron. Both neurons release more transmitter on the distal bundle than on the proximal bundle. The aim of our studies was to investigate the structural basis of this differentiation. Thin sections cut at 50 microns intervals showed a similar number of excitatory synapses on the two bundles. Freeze-fracture views of excitatory synapses showed that synapse size, active zone number per synapse, and intramembrane particle density in the postsynaptic membrane are similar proximally and distally. Active zones at synapses on the distal bundle are larger and contain about 50% more large intramembrane particles, which are thought to include the voltage-gated Ca2+ channels that couple the action potential to transmitter release, than their counterparts on the most proximal bundle. This difference in channel number appears to produce a disproportionate increase in the probability of transmitter release sufficient to account for most of the proximal-distal disparity in the amplitude of the excitatory postsynaptic potential. In contrast, staining the inhibitor for antibodies to the inhibitory neurotransmitter, GABA, showed that it forms more varicosities on the distal bundle than on the proximal bundle. Because most of the synapses are located in the varicosities, differences in synapse number likely regulate the proximal-distal disparity in the amount of inhibitory transmitter released. Therefore, the regional differentiation in the amount of transmitter released in the DAFM appears to be based on two distinct mechanisms. In the inhibitor, transmitter release appears to be regulated differentially by differences in synapse number. In the excitor, transmitter release appears to be regulated differentially from a similar number of synapses by differences in active zone structure.

Differential ultrastructure of synaptic terminals on ventral longitudinal abdominal muscles in Drosophila larvae

The innervation of ventral longitudinal abdominal muscles (muscles 6, 7, 12, and 13) of third-instar Drosophila larvae was investigated with Nomarski, confocal, and electron microscopy to define the ultrastructural features of synapse-bearing terminals. As shown by previous workers, muscles 6 and 7 receive in most abdominal segments "Type I" endings, which are restricted in distribution and possess relatively prominent periodic terminal enlargements ("boutons"); whereas muscles 12 and 13 have in addition "Type II" terminals, which are more widely distributed and have smaller "boutons". Serial sectioning of the Type I innervation of muscles 6 and 7 showed that two axons with distinctive endings contribute to it. One axon (termed Axon 1) has somewhat larger boutons, containing numerous synapses and presynaptic dense bodies (putative active zones for transmitter release). This axon also has more numerous intraterminal mitochondria, and a profuse subsynaptic reticulum around or under the synaptic boutons. The second axon (Axon 2) provides somewhat smaller boutons, with fewer synapses and dense bodies per bouton, fewer intraterminal mitochondria, and less-developed subsynaptic reticulum. Both axons contain clear synaptic vesicles, with occasional large dense vesicles. Approximately 800 synapses are provided by Axon 1 to muscles 6 and 7, and approximately 250 synapses are provided by Axon 2. In muscles 12 and 13, endings with predominantly clear synaptic vesicles, generally similar to the Type I endings of muscles 6 and 7, were found, along with another type of ending containing predominantly dense-cored vesicles, with small clusters of clear synaptic vesicles. This second type of ending was found most frequently in muscle 12, and probably corresponds to a subset of the "Type II" endings seen in the light microscope. Type I endings are thought to generate the 'fast' and 'slow' junctional potentials seen in electrophysiological recordings, whereas the physiological actions of Type II endings are presently not known.