Synaptic development in the crayfish opener muscle

Nerve terminal regions in walking leg opener muscles of several crayfish of different ages (0 to 245 days after hatching) were examined by means of electron microscopy. This muscle is innervated by two axons (excitatory and inhibitory) and at maturity contains three classes of synapse: excitatory and inhibitory neuromuscular synapses, and inhibitory axo-axonal synapses. The muscle itself is initially a syncytium, which gradually becomes subdivided into distinct “muscle fibers” as the animal matures. Innervation was not found in the opener muscle just before or just after hatching, but was present in restricted locations on the inner side of the muscle within a few days of hatching. As the muscle enlarged and became subdivided, innervation appeared in various other locations. Synaptic contacts were located in young stages soon after hatching, and in later stages. Morphological differences characteristic of excitatory and inhibitory nerve terminals could be found even at the earliest stages of innervation. Both excitatory and inhibitory synapses, but particularly the former, showed evidence of progressive enlargement to a final size within the first two months, and no evidence for further enlargement of existing synapses thereafter. Synaptic maturation also involved the appearance of presynaptic “dense bodies” thought to be regions at which transmitter substance is preferentially released. Nerve terminals at different levels of maturation were observed in opener muscles of young crayfish. Clear evidence for differential maturation of the three types of synapse present in this muscle was obtained. The inhibitory neuromuscular synapses attained their final average size and developed their dense bodies sooner than the excitatory neuromuscular synapses. The inhibitory axo-axonal synapses were the last to appear and to mature.     

Stimulation-induced changes at crayfish (Procambarus clarkii) neuromuscular terminals

Summary The fine structure of neuromuscular terminals of the single excitor axon was examined in the limb stretcher muscle of the crayfish Procambarus clarkii. A morphometric comparsion of the neuromuscular terminals of the left and right limbs of a control crayfish showed them to be similiar in qualitative as well as quantitative features. The excitor axon to the stretcher muscle of the right side was stimulated, by backfiring its branches in the adjacent opener muscle, at 20 Hz for 4–5 h per day over 4–5 days. The stretcher muscle on the left side was not stimulated and served as a control. Morphometric analysis of stimulated terminals revealed an increase in the number of dense bars and synaptic vesicles compared to their non-stimulated, contralateral counterparts. Since dense bars are regarded as active sites of transmitter release, changes in their number provide a morphological basis for synaptic plasticity.     

Differences in synaptic output between excitatory and inhibitory motoneurons in a crayfish muscle

A pair of antagonistic motoneurons, one excitatory and one inhibitory, innervates the distal accessory flexor muscle in the walking limb of the crayfish Procambarus clarkii. The number and size of synapses formed by these two axons on the muscle fibers (neuromuscular synapses) and on each other (axo-axonal synapses) were estimated using thin-section electron microscopy. Although profiles of nerve terminals of the two axons occur in roughly equal proportions, the frequency of occurrence of neuromuscular synapses differed markedly: 73% were excitatory and 27% were inhibitory. However, inhibitory synapses were 4–5 times larger than excitatory ones, and consequently, the total contact areas devoted to neuromuscular synapses were similar for both axons. Axo-axonal synapses were predominantly from the inhibitory axon to the excitatory axon (86%), and a few were from the excitatory axon to the inhibitory axon (14%). The role of the inhibitory axo-axonal synapse is presynaptic inhibition, but that of the excitatory axo-axonal synapse is not known. The differences in size of neuromuscular synapses between the two axons may reflect intrinsic determinants of the neuron, while the similarity in total synaptic area may reflect retrograde influences from the muscle for regulating synapse number.     

Regenerated synaptic terminals on a crayfish slow muscle identify with transplanted phasic or tonic axons

Phasic or tonic nerves transplanted onto a denervated slow superficial flexor muscle in adult crayfish regenerated synaptic connections that displayed large or small excitatory postsynaptic potentials (EPSPs), respectively, suggesting that the neuron specifies the type of synapse that forms (Krause et al., J Neurophysiol 80:994-997, 1998). To test the hypothesis that such neuronal specification would extend to the synaptic structure as well, we examined the regenerated synaptic terminals with thin serial section electron microscopy. There are distinct differences in structure between regenerated phasic and tonic innervation. The phasic nerve provides more profuse innervation because innervation sites occurred more frequently and contained larger numbers of synaptic terminals than the tonic nerve. Preterminal axons of the phasic nerve also had many more sprouts than those of the tonic nerve. Phasic terminals were thinner and had a lower mitochondrial volume than their tonic counterparts. Phasic synapses were half the size of tonic ones, although their active zone-dense bars were similar in length. The density of active zones was higher in the phasic compared with the tonic innervation, based on estimates of the number of dense bars per synapse, per synaptic area, and per nerve terminal volume. Because these differences mirror those seen between phasic and tonic axons in crayfish muscle in situ, we conclude that the structure of the regenerated synaptic terminals identify with their transplanted axons rather than with their target muscle. Therefore, during neuromuscular regeneration in adult crayfish, the motoneuron appears to specify the identity of synaptic connections.     

Fine structure of comparable synapses in a mature and larval lobster muscle

Neuromuscular synapses from the single excitor axon to the proximal accessory flexor muscle (PAFM) was studied by serial section electron microscopy in a 1st stage larval (< 0.1 g) and a large adult (6.8 kg) lobster. The adult innervation of a lateral and a medial fiber, physiologically identified as low- and high-output respectively, was similar in the number and mean size of synapses but had significantly larger pre-synaptic dense bars for the high-output synapses. This correlation between quantal transmitter output and pre-synaptic dense bars and the appearance of exocytotic profiles along the dense bars strongly implicates the bars as active sites of transmitter release. Moreover the mature innervation is differentiated on the basis that the percentage of dense bar area to synaptic area is 9% for the low-output type compared to 22% for its high-output counterpart. In the larval PAFM the excitatory axon has not proliferated many branches and the innervation is therefore localized to groups of fibers in the lateral, medial and central regions of the muscle rather than to individual fibers. The lateral and medial sites of innervation representing putative low- and high-output types respectively (because of their location) do not differ in the size and number of pre-synaptic dense bars thereby suggesting a similarity in quantal synaptic transmission. However the percentage of dense bar area to synaptic area is 40% for the lateral site compared to 67% for the medial site. Since this is a trend mimicking the mature innervation it shows an early stage in the differentiation of low-and high-output synapses. Furthermore the main axon provides half of the total innervation in the larval PAFM but none in the adult thereby demonstrating a restructuring of multiterminal innervation.     

Inhibitory innervation of a lobster muscle

Summary Inhibitory neuromuscular synapses formed by the common inhibitor (CI) neuron on the distal accessory flexor muscle (DAFM) in the lobster, Homarus americanus, were studied with electrophysiological and electron-microscopic (thin-section and freeze-fracture) techniques. Postsynaptic inhibition as indicated by inhibitory junctional potentials was several-fold stronger on distal compared to proximal muscle fibers. This difference correlated with the results of serial thin-section studies, which showed more inhibitory synapses on distal fibers than on their proximal counterparts. Effects of postsynaptic inhibition on excitatory junctional potentials via current shunting had a morphological correlate in the spatial relationship between inhibitory and excitatory synapses on the distal fibers. Inhibitory synapses were larger than their excitatory counterparts and had fewer glial processes. In freeze-fracture views, inhibitory synapses did not appear as raised plateaus in the P-face as do excitatory synapses, and their active zones were more widely scattered. The intramembrane particles in the inhibitory postsynaptic membrane-representing neurotransmitter receptors-are arranged in parallel rows in the sarcolemmal P-face and have complementary furrows in the sarcolemmal E-face. Altogether, our findings help to describe a population of inhibitory neuromuscular synapses formed by the CI neuron in lobster muscle.     

Presynaptic dense bars at neuromuscular synapses of the lobster,Homarus americanus

Summary The threedimensional ultrastructure of presynaptic dense bars was examined by serial section electron microscopy in the excitatory neuromuscular synapses of the accessory flexor muscle in the limbs of larval, juvenile, and adult lobsters. The cross-sectional profile of the dense bar resembles an asymmetric hourglass, the part contacting the presynaptic membrane being larger than that projecting into the terminal. The bar has a height of 55–65 nm and varies in length from 75–600 nm. In its dimensions it resembles the dense projections in the synapses of the CNS of insects and vertebrates. The usual location of these dense bars is at well defined synapses, though a few are found at extrasynaptic sites either in the axon or terminal. In the latter case the bars are close to synapse-bearing regions, particularly in the larval terminals, suggesting that the extrasynaptic bars denote early events in synapse formation. In all cases the bars are intimately associated with electron lucent, synaptic vesicles located on either side, in the indentation of its hourglass-shaped cross sectional profile. The vesicles occur along the length of the bar and contact the presynaptic membrane. Consequently the dense bar may serve to align the vesicles at the presynaptic membrane prior to exocytosis. A similar role has been suggested for the presynaptic dense bodies at the neuromuscular junction of the frog, where synaptic vesicles form a row on either side of this structure.Supported by Muscular Dystrophy Association of Canada and NSERCC. Generous use of laboratory facilities at Woods Hole was provided by the late Fred Lang     

Proliferation and relocation of developing lobster neuromuscular synapses

The development of multiterminal innervation from a single identifiable excitatory motoneuron to the lobster distal accessory flexor muscle (DAFM) was studied by serial section electron microscopy. The number, size, and location of neuromuscular synapses and presynaptic dense bars within the peripheral branching pattern of the axon was determined in cross sections of the DAFM in 1st (24-hr-old)-, 4th (2-week-old)-, and 12th (1-year-old)-stage lobsters. The mean size of synapses remains fairly constant in these three stages but synaptic density, i.e., the number of synapses per unit length of fiber, increased more than 20-fold between the 1st and 4th stages and more than 5-fold between the 4th and 12th stages. Synaptic surface area per fiber length showed a parallel increase. Consequently there is a proliferation of synapses along the length of individual muscle fibers during primary development. Furthermore from the 1st stage where only a few fibers are innervated, synapses proliferate to many more fibers in the 4th and to all fibers in the 12th stage. The neuromuscular synapses are distributed in different proportions within the axonal branching pattern in the three stages. Based on the number and size of synapses and presynaptic dense bars, the main axon and primary branches provide almost equal amounts of innervation in the 1st stage. With further branching in the 4th stage, the main axon accounts for only 20–25% of the innervation; the primary branches for 45% and other finer branches the remainder. By the 12th-stage synapses are found only on branches other than the main axon and its primary offshoots. There is therefore a shift in innervation from the main axon to the primary branches and then to the finer branches during primary development. This shift in innervation involves the formation of new synaptic terminals and the restructuring of existing ones into axonal areas. In this way the multiterminal innervation arising from an identifiable motoneuron is remodeled.     

THREE-DIMENSIONAL ULTRASTRUCTURE OF THE CRAYFISH NEUROMUSCULAR APPARATUS

The synapse-bearing nerve terminals of the opener muscle of the crayfish Procambarus were reconstructed using electron micrographs of regions which had been serially sectioned. The branching patterns of the terminals of excitatory and inhibitory axons and the locations and sizes of neuromuscular and axo-axonal synapses were studied. Excitatory and inhibitory synapses could be distinguished not only on the basis of differences in synaptic vesicles, but also by a difference in density of pre- and postsynaptic membranes. Synapses of both axons usually had one or more sharply localized presynaptic "dense bodies" around which synaptic vesicles appeared to cluster. Some synapses did not have the dense bodies. These structures may be involved in the physiological activity of the synapse. Excitatory axon terminals had more synapses, and a larger percentage of terminal surface area devoted to synaptic contacts, than inhibitory axon terminals. However, the largest synapses of the inhibitory axon exceeded in surface area those of the excitatory axon. Both axons had many side branches coming from the main terminal; often, the side branches were joined to the main terminal by narrow necks. A greater percentage of surface area was devoted to synapses in side branches than in the main terminal. Only a small fraction of total surface area was devoted to axo-axonal synapses, but these were often located at narrow necks or constrictions of the excitatory axon. This arrangement would result in effective blockage of spike invasion of regions of the terminal distal to the synapse, and would allow relatively few synapses to exert a powerful effect on transmitter release from the excitatory axon. A hypothesis to account for the development of the neuromuscular apparatus is presented, in which it is suggested that production of new synapses is more important than enlargement of old ones as a mechanism for allowing the axon to adjust transmitter output to the functional needs of the muscle.     

Heterogeneity of excitatory synapses at the ends of single muscle fibers in lobster,Homarus americanus

Crustacean neuromuscular synapses arising from a single excitor axon are known to be well differentiated among different muscle fibers but little is known about their condition along single fibers. Focal recording techniques were used to examine the quantal transmitter release and facilitation properties of synapses in the single excitatory innervated distal accessory flexor muscle of the lobster, Homarus americanus. Synapses were reliably differentiated with respect to quantal output so that those located near the tendon end were 1.15–4.12 times greater than those at the opposite, exoskeletal end (p < 0.01, paired t-test). Regional differences were also seen in the amount of facilitation determined from twin pulse experiments. The fine structural basis for these differences was determined by serial section electron microscopy of 10-μm segments at each end to ensure that the area of focal recording was sampled. No quantitative differences were found in the terminals or synapses in the two regions. Instead, the physiological diversity was correlated with number and size of presynaptic dense bars. Thus, the tendon end had a greater number and larger mean surface area of dense bars compared to the exoskeletal end. This heterogeneity of excitatory multiterminal innervation is correlated with the axonal branching pattern. Thus, the main axon and the larger primary axon branches lie in close proximity to the tendon end of the muscle fibers, whereas the exoskeletal end is innervated by smaller secondary and tertiary axonal branches. This proximity to the large axonal branches of the higher quantal output synapses at the tendon end may be regulated by some neural influence including a timing of innervation and/or access to greater amounts of metabolites in the larger branches which may be conducive to forming high-output synapses.     

Differential facilitation of high- and low-output nerve terminals from a single motoneuron.

In the crayfish opener neuromuscular preparation, regional differences in synaptic transmission are observed among the terminals of a single motoneuron. With a single stimulus, the high-output terminals of the proximal region of the muscle produce a larger excitatory postsynaptic potential than do the low-output terminals of the central region of the muscle. We tested the hypothesis that the low-output terminals exhibit more facilitation than do high-output terminals for twin-pulse, train, and continuous-stimulation paradigms. Previous studies have not employed several stimulation paradigms to induce facilitation among high- and low-output terminals of a single motoneuron. We found that the high-output terminals on the proximal fibers facilitate more than the low-output terminals on the central muscle fibers, in contrast with previous studies on similar muscles. The difference in measured facilitation is dependent on the stimulation paradigm. These results are important because ultrastructural differences between these high- and low-output terminals are known and can be used for correlation with physiological measurements. Short-term facilitation is a form of short-term memory at the synaptic level, and the processes understood at the crayfish neuromuscular junction may well be applicable to all chemical synapses.     

A peptide action in a lobster neuromuscular preparation

The neuropeptide proctolin causes a sustained contraction of the opener muscle of the dactyl of the lobster walking leg. This substance acts directly on the muscle at concentrations as low as 10^?10M. The contraction is dependent on extracellular calcium. Neither a significant depolarization nor a detectable change in the input resistance accompanies the response. No presynaptic action of proctolin is indicated; excitatory and inhibitory junctional potential sizes and the frequency of spontaneous miniature excitatory junctional potentials are unaffected.     

Structural definition of the neuromuscular system in the swimming-paddle opener muscle of blue crabs

Blue crabs are excellent swimmers, using their highly modified last pereiopods as sculling paddles. Hence, the hypertrophied paddle opener muscle was examined for adaptations of its motor innervation by an excitor and a specific inhibitor axon. The muscle has a uniform composition of slow fibers with long (6-12 microm) sarcomere lengths. Individual fibers are richly innervated with approximately two-thirds excitatory and one-third inhibitory innervation. The profuse excitatory innervation reflects the high activity levels of this motoneuron in swimming. Adaptation to sustained activity associated with swimming is also reflected in the motor nerve terminals by a high concentration of energy source, which is equally divided between glycogen granules and mitochondria, the former providing a more rapid source of energy. The excitor axon makes predominantly neuromuscular synapses, but also a few synapses onto the inhibitor axon. The location of these excitatory axoaxonal synapses suggests regional modulation of the inhibitor axon. The specific inhibitor axon makes less than two-thirds of its synapses with the muscle fiber, regulating contraction via postsynaptic inhibition. The remaining inhibitory synapses are onto the excitor axon, signaling very strong presynaptic inhibition. Such presynaptic inhibition will effectively decouple the opener muscle from the stretcher muscle even though both are innervated by a single excitor axon.     

Intracellular pH of crab and crayfish muscle fibre types during GABA application and inhibitory nerve stimulation

The inhibitory motoneurons of crustaceans form synapses both with the sarcolemma of muscle fibres and with the very distal branchings of the excitatory motoneurons. The transmitter of these synapses is GABA (γ-aminobutyric acid) which is known to open Cl⁻ channels. Studies on the dactyl opener muscle of crayfish suggest that application of GABA not only leads to an increase in the Cl⁻ permeability but also to a considerable HCO⁻ ₃ conductance that causes an intracellular acidification. To investigate possible physiological implications, we measured the intracellular pH of various muscle fibre types of crayfish and crab using pH-sensitive microelectrodes. Independent of the presence or absence of inhibitory innervation, bath application of 10⁻⁵ mol l⁻¹ GABA led to acidification in all fibre types (pH change: 0.14 ± 0.08, n=11). In no preparation was a change in intracellular pH observed upon stimulation of specific or common inhibitory motoneurons with 10–40 pulses s⁻¹ for 2–5 min. The results suggest that HCO⁻ ₃ conductance cannot be activated through synaptic GABA receptors. However, all crustacean muscle fibre types seem to possess extrasynaptic GABA-sensitive channels that exhibit a considerable HCO⁻ ₃ conductance. The physiological importance of these channels remains to be elucidated. Accepted: 13 July 2000     

Fast-axon synapses of a crab leg muscle

Neuromuscular synapses of the "fast" excitatory axon supplying the main extensor muscle in the leg of the shore crab Pachygrapsus crassipes were studied with electrophysiological and electron-microscopic techniques. Electrical recording showed that many muscle fibers of the central region of the extensor muscle responded only to stimulation of the fast axon, and electron microscopy revealed many unitary subterminal axon branches. Maintained stimulation, even at a low frequency, resulted in depression of the excitatory junctional potentials (EJPs) set up by the fast axon but EJPs of different muscle fibers depressed at different rates, indicating some physiological heterogeneity among the fast-axon synapses. Focal recording at individual synaptic sites on the surfaces of the muscle fibers showed quantal contents ranging from 1.4 to 5.5 at different synapses; these values are relatively high in comparison with similar determinations made in the crayfish opener muscle. Synapse-bearing nerve terminals were generally relatively small in diameter and filiform, with many individual synaptic contact areas of uniform size averaging 0.6 micron2. All of the individual synapses had a presynaptic "dense body" at which synaptic vesicles clustered. If these structures represent release points for transmitter quanta, the initial high quantal content would have an ultrastructural basis. The mitochondial content of the nerve terminals, the synaptic vesicle population, and the specialized subsynaptic sarcoplasm were all much reduced in comparison with tonic axon synaptic regions in this and other crustaceans. The latter features may be correlated with the relatively infrequent use of this axon by the animal, and with rapid fatigue.     

Peptidergic motoneurons in the buccal ganglia of Aplysia californica Immunocytochemical,morphological, and physiological characterizations

Summary We used physiological recordings, intracellular dye injections and immunocytochemistry to further identify and characterize neurons in the buccal ganglia of Aplysia calif ornica expressing Small Cardioactive Peptide-like immunoreactivity (SCP-LI). Neurons were identified based upon soma size and position, input from premotor cells B4 and B5, axonal projections, muscle innervation patterns, and neuromuscular synaptic properties. SCP-LI was observed in several large ventral neurons including B6, B7, B9, B10, and B11, groups of s1 and s2 cluster cells, at least one cell located at a branch point of buccal nerve n2, and the previously characterized neurons B1, B2 and B15.B6, B7, B9, B10 and B11 are motoneurons to intrinsic muscles of the buccal mass, each displaying a unique innervation pattern and neuromuscular plasticity. Combined, these motoneurons innervate all major intrinsic buccal muscles (I1/I3, I2, I4, I5, I6). Correspondingly, SCP-LI processes were observed on all of these muscles. Innervation of multiple nonhomologous buccal muscles by individual motoneurons having extremely plastic neuromuscular synapses, represents a unique form of neuromuscular organization which is prevalent in this system. Our results show numerous SCPergic buccal motoneurons with widespread ganglionic processes and buccal muscle innervation, and support extensive use of SCPs in the control of feeding musculature.Abbreviations SCP-LI small cardioactive peptide-like immunoreactivity - PSC postsynaptic current - EPSP excitatory postsynaptic potential - IPSP inhibitory postsynaptic potential - FI facilitation index - TMR time to maximal response     

Functional roles of peptide cotransmitters at neuromuscular synapses inAplysia

Neuromuscular synapses inAplysia have been used as model systems to study peptidergic cotransmission. Here we describe neuromuscular preparations in which it has been possible to investigate the physiological consequences of peptide transmitter release in detail. In the first preparation, the release of peptide cotransmitters from identified motor neuron B15 has been shown to be sensitive to the pattern of stimulation. High frequencies and long burst durations evoke peptide release that modulates muscle contractions in a manner similar to that produced by exogenous cotransmitter. By contrast, the release of the same peptide transmitters from motor neuron B1 show little dependence on pattern. We conclude that there are no stimulation patterns that are prerequisites for peptide release. Peptide cotransmitter release from motor neuron B47 has also been studied. B47, depending on the stimulation pattern, uses either ACh, which acts as a conventional inhibitory transmitter, or Ach plus neuropeptides, which act as excitatory modulatory cotransmitters. Thus, neuropeptide cotransmitters have the capability to greatly increase synaptic plasticity at neuromuscular synapses.     

Comparison of fast and slow synaptic terminals in lobster muscle

Summary Synaptic terminals of fast (FCE) and slow (SCE) excitatory neurons were physiologically identified on separate fibres of one muscle, the closer muscle in lobster claws. The innervation by these identified fibers was demonstrated over long distances (7–21 m) by examining serial thin sections at periodic intervals. The ultrastructure of each type of innervation was consistent both qualitatively and quantitatively in two separate samples. The FCE innervation is relatively simple in having consistently small-diameter terminals each forming a single long synapse, with few synaptic vesicles, and little if any postsynaptic apparatus. The SCE innervation is more complex in having larger-diameter but more variable terminals forming several short synapses, with many synaptic vesicles and an extensive postsynaptic apparatus. These differences in the size of the synapses and the number of synaptic vesicles parallel differences in transmitter release and fatigue sensitivity characteristic of the two types of innervation. The degree of elaboration of the postsynaptic apparatus may reflect differences in the amount of transmitter taken up after release. Our data reveal for the first time in a single muscle differences between FCE and SCE innervation previously reported in different muscles and in different species.Supported by grants from NIH (NINCDS) to A.G. Humes and the late Fred Lang and from NSERC and Muscular Dystrophy Assoc. of Canada to C.K. GovindWe thank Lena Hill for her technical expertise and critical evaluation of the study, and Dr. A.G. Humes for providing research facilities     

Synaptic differentiation between two phasic motoneurons to a crayfish fast muscle

Synaptic differentiation among crustacean phasic motoneurons was investigated by characterizing the synaptic output and nerve terminal morphology of the two axons to the adductor exopodite muscle in the crayfish uropod. The muscle is of the fast type with short sarcomeres (2–3 μm) and a low thin to thick filament number (6:1). On single muscle fibers, excitatory postsynaptic potentials generated by the large-diameter axon are significantly larger than those by the small-diameter axon suggesting a presynaptic origin for these differences. Nerve terminals arising from these two axons have typical phasic features, filiform shape and a low (6–8%) mitochondrial density. Synaptic contacts are similar in size between the two axons as is the length and number of active zone dense bars at these synapses. The large-diameter axon, however, exhibits a twofold larger area of nerve terminal than the small-diameter axon resulting in a higher density of synapses per muscle fiber. Hence, differences in synaptic density may in part account for differences in synaptic output between these paired phasic axons. Electronic Publication     

The Distribution of Pre- and Postsynaptic Inhibition at Crustacean Neuromuscular Junctions

The relative contribution of pre- and postsynaptic mechanisms to peripheral inhibition has been analyzed in the abdominal slow flexor muscles of crayfish and lobsters. The conductance of the muscle fiber membrane may be increased to five or more times its resting value by repetitive stimulation of the peripheral inhibitory axon, and this effect accounts for all of the attenuation exerted by the inhibitor against excitatory junctional potentials. No "critical interval" has been found at which an inhibitory nerve impulse produces anomalously large reduction of a following depolarizing junctional potential; electrotonic depolarizations and junctional potentials are identically affected under all phase conditions. The presynaptic inhibitory mechanism is, therefore, absent in this system. In the dactyl opener muscle, on the contrary, most of the attenuation of excitatory junctional potentials is achieved presynaptically, though equally large postjunctional conductance changes are also seen (Dudel and Kuffler, 1961). The difference is correlated with a difference in the reflex operation of the two muscles. Reflex inhibition in the abdominal slow flexors is primarily central, whereas in the dactyl opener, inhibition is brought about by an increase in inhibitory nerve discharge frequency without central suppression of the single excitatory axon. The function of peripheral inhibition in the abdominal flexors is presumably to terminate residual depolarization by reducing the long time-constant of the muscle fibers.