Potential changes recorded from the frog motor nerve terminal during its activation

The Frog Motor Nerve Terminal Has Very Brief Action Potentials and Three Electrical Regions Predicted to Differentially Control Transmitter Release

The action potential (AP) waveform controls the opening of voltage-gated calcium channels and contributes to the driving force for calcium ion flux that triggers neurotransmission at presynaptic nerve terminals. Although the frog neuromuscular junction (NMJ) has long been a model synapse for the study of neurotransmission, its presynaptic AP waveform has never been directly studied, and thus the AP waveform shape and propagation through this long presynaptic nerve terminal are unknown. Using a fast voltage-sensitive dye, we have imaged the AP waveform from the presynaptic terminal of male and female frog NMJs and shown that the AP is very brief in duration and actively propagated along the entire length of the terminal. Furthermore, based on measured AP waveforms at different regions along the length of the nerve terminal, we show that the terminal is divided into three distinct electrical regions: A beginning region immediately after the last node of Ranvier where the AP is broadest, a middle region with a relatively consistent AP duration, and an end region near the tip of nerve terminal branches where the AP is briefer. We hypothesize that these measured changes in the AP waveform along the length of the motor nerve terminal may explain the proximal-distal gradient in transmitter release previously reported at the frog NMJ.SIGNIFICANCE STATEMENT The AP waveform plays an essential role in determining the behavior of neurotransmission at the presynaptic terminal. Although the frog NMJ is a model synapse for the study of synaptic transmission, there are many unknowns centered around the shape and propagation of its presynaptic AP waveform. Here, we demonstrate that the presynaptic terminal of the frog NMJ has a very brief AP waveform and that the motor nerve terminal contains three distinct electrical regions. We propose that the changes in the AP waveform as it propagates along the terminal can explain the proximal-distal gradient in transmitter release seen in electrophysiological studies.

Modulation of presynaptic Ca(2+) currents in frog motor nerve terminals by high pressure

Presynaptic Ca(2+) -dependent mechanisms have already been implicated in depression of evoked synaptic transmission by high pressure (HP). Therefore, pressure effects on terminal Ca(2+) currents were studied in Rana pipiens peripheral motor nerves. The terminal currents, evoked by nerve or direct stimulation, were recorded under the nerve perineurial sheath with a loose macropatch clamp technique. The combined use of Na(+) and K(+) channel blockers, [Ca(2+) ]o changes, voltage-dependent Ca(2+) channel (VDCC) blocker treatments and HP perturbations revealed two components of presynaptic Ca(2+) currents: an early fast Ca(2+) current (ICaF ), possibly carried by N-type (CaV 2.2) Ca(2+) channels, and a late slow Ca(2+) current (ICaS ), possibly mediated by L-type (CaV 1) Ca(2+) channels. HP reduced the amplitude and decreased the maximum (saturation level) of the Ca(2+) currents, ICaF being more sensitive to pressure, and may have slightly shifted the voltage dependence. HP also moderately diminished the Na(+) action current, which contributed to the depression of VDCC currents. Computer-based modeling was used to verify the interpretation of the currents and investigate the influence of HP on the presynaptic currents. The direct HP reduction of the VDCC currents and the indirect effect of the action potential decrease are probably the major cause of pressure depression of synaptic release.

Single-pixel optical fluctuation analysis of calcium channel function in active zones of motor nerve terminals

We used high-resolution fluorescence imaging and single-pixel optical fluctuation analysis to estimate the opening probability of individual voltage-gated calcium (Ca(2+)) channels during an action potential and the number of such Ca(2+) channels within active zones of frog neuromuscular junctions. Analysis revealed ∼36 Ca(2+) channels within each active zone, similar to the number of docked synaptic vesicles but far less than the total number of transmembrane particles reported based on freeze-fracture analysis (∼200-250). The probability that each channel opened during an action potential was only ∼0.2. These results suggest why each active zone averages only one quantal release event during every other action potential, despite a substantial number of docked vesicles. With sparse Ca(2+) channels and low opening probability, triggering of fusion for each vesicle is primarily controlled by Ca(2+) influx through individual Ca(2+) channels. In contrast, the entire synapse is highly reliable because it contains hundreds of active zones.

An analysis of facilitation of transmitter release at the neuromuscular junction of the frog

1. Experiments were done on Mg-blocked neuromuscular junctions of the frog to study in detail the magnitude and time course of facilitation of the end-plate potential (e.p.p.).2. When two shocks were applied to the motor nerve with an interval of 5 msec or less between them, the amplitude of the second e.p.p. was facilitated by approximately 100%. This facilitation decreased as the interval was lengthened.3. The facilitation could be separated into two components on the basis of the time course of its decay as the interval between the two shocks was increased. The first component decayed exponentially after the conditioning shock with a time constant of about 35 msec. The second became apparent 60-80 msec after the conditioning shock, rose to a maximum of approximately 15% at about 120 msec and decayed thereafter with a time constant of the order of 250 msec.4. The growth of e.p.p. amplitude during short trains of repetitive stimulation at frequencies up to 100/sec and its subsequent decay could be predicted by assuming that the magnitude and time course of both components of facilitation were the same for every shock in the train and that these individual facilitatory effects summed linearly.

Temperature effect on proximal to distal gradient of quantal release of acetylcholine at frog endplate

The conduction velocity of the nerve terminal, mean quantal content, and release latencies of uniquantal endplate currents (EPCs) were recorded in proximal, central, and distal parts of the terminal by extracellular pipettes located 5, 50, and 100 microm from the end of myelinated nerve trunk. The spike conduction velocity, minimal latency, modal value of the latency histograms, and time interval during which 90% of EPCs released (P90) at distal, central, and proximal part of the frog nerve terminal have different temperature dependency between 10 degrees and 28 degrees C. As shown by the size and time-course of reconstructed multiquantal EPCs, the secretion synchronization, which is greatest in distal parts, compensates at least partly for the progressive slowing of spike conduction velocity in the proximodistal direction, in particular at lower temperatures.

Non-uniform responses to Ca2+ along the frog neuromuscular junction: effects on the probability of spontaneous and evoked transmitter release

Spontaneous and evoked transmitter release activity was studied during selective application of Ca2+ in proximal (near the first contact of the axon on the muscle fiber) and distal regions of the frog neuromuscular junction. A new technique called "Microperfusion" was developed, which allowed us to apply a 30-microns-wide Ca2+ stream from an external pipette. The spread of this Ca2+ stream was monitored by adding Blue Dextran (40 mg/ml) to the Ca2+ solution. Microperfusion with a Ca2(+)-free Ringer containing Blue Dextran did not affect the miniature endplate potential frequency or amplitude. Changes of spontaneous transmitter release were studied either during microperfusion of Ringer containing 5 mM Ca2+ or during microperfusion of 2 mM Ca2+ simultaneously with the stimulation of the motor nerve. This second procedure also permitted study of the characteristics of evoked release. Microperfusion of Ca2+ induced a larger and more rapid increase in the miniature endplate potential frequency in proximal than in distal regions. The time required for the miniature endplate potential frequency to return to the control value after Ca2+ microperfusion was longer than the time needed to increase the frequency and this decay period was longer in the proximal region than in the distal one. Moreover, miniature endplate potentials produced in proximal regions, were typically larger and more variable than those produced in distal regions. In five experiments, the endplate potentials produced by 100-200 pulse pairs (interval of 15 ms at every 2 s) were recorded intracellularly during the microperfusion. The quantal content of the first endplate potential of the pair (EPP1) was systematically smaller in distal regions than in proximal regions. The percentage of failures and the coefficients of variation were higher in distal than in proximal regions, indicating a larger variability of quantal content. The frequency facilitation was not different between the two regions, but, however, the second stimuli of the pair usually produced a net increase of transmitter release which was greater in proximal than distal regions. Our experiments demonstrate that both the spontaneous and the evoked release are more responsive to Ca2+ application in the proximal than in the distal regions of the frog neuromuscular junction.

Inhibition of Ca2+ inflow at nerve terminals of frog muscle blocks facilitation while phasic transmitter release is still considerable

Action potentials were triggered in the motor nerve by a suction electrode and calcium currents (iCa) in the nerve terminals were measured by means of a perfused macro-patch-clamp electrode on the distal portion of the end-plates. Postsynaptic currents were blocked by adding d-tubocurarine, whereas presynaptic Na+ (iNa) and K+ (iK) currents were blocked by adding tetrodotoxin (TTX), tetraethylammonium and 3,4-diaminopyridine, respectively, to the perfusate of the electrode. The current components which could be suppressed by addition of Cd2+ to the perfusate were taken as presynaptic iCa. The observed effects on the presynaptic current components were very similar to those reported previously. If the electrode was perfused with Ringer's solution containing the blockers for iNa and iK, the same, obviously complete block of iCa was obtained by 50 and 100 microM Cd2+, an average of 96% block by 20 microM Cd2+ and 50% block by about 5 microM Cd2+. Using the same type of electrode and similar locations on motor nerve terminals, postsynaptic quantal currents and twin-pulse facilitation (Fd) were elicited by variable-duration (0.5-3 ms) depolarizing pulses. When the electrode was perfused with Ringer's solution containing TTX, 20 microM Cd2+ added to the perfusate reduced the rate of phasic release of quanta insignificantly for short depolarizing pulses and by a factor of about 10 for longer pulses. Fd was blocked almost completely. Addition of 50 microM Cd2+ to the perfusate had a greater depressive effect on release after short depolarizing pulses and reduced release after longer pulses by a factor of about 100.(ABSTRACT TRUNCATED AT 250 WORDS)

Terminal sprouting in mouse neuromuscular junctions poisoned with botulinum type A toxin: morphological and electrophysiological features

Functional properties of terminal sprouts elicited by an in vivo injection of Clostridium botulinum type A toxin were studied in endplates of the Levator auris longus muscle of the mouse poisoned from a few days to 28 days beforehand. For this purpose, morphological observations of the extent of terminal sprouts and localization of acetylcholine receptors was performed in whole mount preparations. Sprouts appeared as thin unmyelinated filaments that run usually parallel to the longitudinal axis of the muscle fibres; labelling acetylcholine receptors revealed their line-shaped accumulation co-localized with the sprouts. In addition, presynaptic membrane currents elicited by nerve stimulation were recorded by external electrodes applied under visual control onto the membrane of pre-existing motor endings and newly formed sprouts. These recordings showed the presence of widespread triphasic waveforms which indicated active impulse propagation of the action potential over most of the length of the poisoned endings. Ca2+ influx and Ca2(+)-dependent K+ currents in the sprout membrane were found to be similar to those described in unpoisoned endings. The presence of normal Ca2+ influx, upon active depolarization, in the terminal sprout membranes together with the localization of acetylcholine receptors in front of these membranes, indicates that the terminal sprouts may play a role in the recovery of neuromuscular transmission after Clostridium botulinum poisoning.

Dependence of spontaneous release at frog junctions on synaptic strength, external calcium and terminal length

1. The calcium dependence of spontaneous transmitter release from nerve terminals of different lengths was examined at neuromuscular junctions in frog muscle. Miniature endplate potential (MEPP) frequency was positively correlated with the endplate potential (EPP) quantal content and was dependent on external Ca2+. The higher the resting MEPP frequency in a 0.25 mM-Ca2+ Ringer solution, the greater the dependence on external Ca2+. MEPP frequency in all terminals dropped to approximately the same low level in a Ca2(+)-free Ringer solution containing EGTA. This suggests that terminals with higher release levels have a larger Ca2+ influx at rest. 2. Several tests were done to try to characterize the mode of Ca2+ entry into resting terminals. omega-Conotoxin (omega-CgTx) blocked evoked release and reduced MEPP frequency, but not as effectively as zero Ca2(+)-EGTA Ringer solution. Some component of Ca2+ influx thus appears to enter through channels insensitive to omega-CgTx. Tetrodotoxin (TTX) did not affect MEPP frequency, indicating that the Ca2+ did not enter through TTX-sensitive Na+ channels that might be opening spontaneously at rest. Hyperpolarization of the terminal by reducing the K+ in the Ringer solution caused no consistent differences in MEPP frequency, suggesting that the Ca2+ influx is relatively insensitive to small changes in membrane potential around the resting level. Strong buffering of the Ringer solution with citrate, to overwhelm any differences in Ca2+ buffering within different junctional clefts, had no significant effect on the MEPP frequency. 3. Evidence that the Na(+)-Ca2+ exchanger helps set the internal Ca2+ level was obtained. Reduction of the Na+ concentration in the Ringer solution caused increases in MEPP frequency ranging from 6 to 440%. However, these changes were not correlated with resting MEPP frequency, hence differences in MEPP frequency probably are not the result of differences in Na(+)-Ca2+ exchanger function in terminals having a uniform Ca2+ leak. 4. Although MEPP frequency was generally correlated with quantal content, in subsets of junctions grouped according to their similar quantal contents, there was a positive correlation between MEPP frequency and terminal length. 5. In zero Ca2(+)-EGTA Ringer solution, the low residual MEPP frequency is independent of terminal length, even when MPP frequency is sharply increased by tetanic stimulation.

Ionic basis of tetanic and post-tetanic potentiation at a mammalian neuromuscular junction

1. The ionic basis of tetanic and post-tetanic potentiation (TP and PTP) was studied at the rat soleus neuromuscular junction (NMJ), using the miniature endplate potential (MEPP) frequency as an index for transmitter release. Conventional intracellular recording and computer-assisted data analysis were employed. 2. The experimental results in this study indicate that contrary to previous suggestions, there is a substantial similarity in the ionic basis of TP and PTP at the mammalian and amphibian motor nerve terminals which can be subdivided into [Ca2+]o-dependent and [Ca2+]o-independent parts. 3. Tetanic and post-tetanic increase in MEPP frequency at the rat soleus NMJ is similar to that at the frog NMJ in the following aspects: (i) Tetanic potentiation is substantially larger in calcium-containing solutions than in calcium-deficient solutions. About 90% of tetanic potentiation is contributed by extracellular calcium. (ii) Increase in [Mg2+]o reduces tetanic potentiation in calcium-containing solutions and enhances TP in calcium-defient solutions. Elevated [Mg2+]o prolongs the post-tetanic potentiation both in calcium-containing and in calcium-deficient solutions. (iii) A post-tetanic jump in MEPP frequency was observed in 44% of the experiments performed in calcium-deficient solutions. (iv) The augmentation phase of post-tetanic potentiation, evident in calcium-containing solutions, is completely abolished by removal of [Ca2+]o. (v) Tetanic and post-tetanic potentiations are enhanced by increasing the rate and duration of tetanic stimulation in calcium-containing solutions. 4. The [Ca2+]o-independent part of tetanic potentiation is presumably due to entry of sodium ions and their accumulation in the nerve terminal, since it is increased by measures known to inhibit the sodium pump: reduction in [K+]o and partial substitution of sodium by lithium. 5. Sodium ions contribute substantially to the [Ca2+]o-independent part of posttetanic potentiation, since its duration is markedly prolonged by ouabain, reduction in [K+]o and partial substitution of sodium by lithium. 6. Tetanic potentiation is manifested earlier in calcium-containing media than in calcium-deficient media. This difference may indicate that sodium entry into the terminal during tetanic stimulation is at locations remote from the releasing sites. Alternatively, this time difference may be due to the delay between intracellular sodium accumulation and the increase in transmitter release.

Non-uniform release at the frog neuromuscular junction: evidence of morphological and physiological plasticity

The frog neuromuscular junction (NMJ) is a fusiform structure parallel to the muscle fiber with a few secondary and tertiary branches. Both sprouting and regression can occur on the same nerve terminal, suggesting a continuous on-going remodelling of the mature neuromuscular junction. Thus, the frog NMJ is a dynamic structure. Ultrastructural observations of the nerve terminal suggest that the active zones are distributed equally along the mature nerve terminal. Disorganized active zones have however been observed in distal regions. The density of synaptic vesicles is also uniform throughout the whole structure. However, mitochondria appear to be more abundant in the very distal regions of the nerve terminal. The postjunctional folds and the cholinergic receptors are also uniformly distributed along the NMJ. However, during remodelling periods, the distributions of postjunctional folds and of cholinergic receptors are not uniform in the degenerating and regenerating regions. Fig. 1 summarizes these morphological data. The frequency of spontaneous release (MEPPs) at the NMJ is higher in the proximal region than in the distal regions and recent evidence suggests that the mean MEPP amplitude is higher in the proximal than in the distal portions. Evoked transmitter release is also non-uniform along the frog NMJ. As for spontaneous release, it is higher in the proximal regions than in the distal regions. Failures of the active propagation of the PNAP at low safety points, such as the end of the myelinated axon and the branching points, may be one of the mechanisms responsible for unequal evoked release. It is also possible that the PNAP does not actively invade the whole extend of the nerve terminal since Na+ channels are absent from the distal regions. Fig. 2 summarizes these physiological data.

Two different presynaptic calcium currents in mouse motor nerve terminals

Extracellular recordings of potential changes under the perineural sheath of nerve bundles close to some of the nerve terminals were performed using the M. triangularis sterni of the mouse. The nerve signals consisted of a predominant double-peaked negativity which was often preceded by a small positive deflection. While the first negative peak is related to the propagating nerve action potential, the second negative deflection can be attributed to a potassium conductance since it was selectively blocked by tetraethylammonium (TEA) or 3,4-diaminopyridine (3,4-DAP). Combined application of TEA and 3,4-DAP gave rise to a prolonged positive-going wave which was blocked by Cd2+, thus, indicating its underlying cause to be a Ca current. Ionophoretic application of TEA and Cd2+ to the endplates affected potassium and calcium components of the subendothelial signals, respectively, thus indicating their presynaptic origin. This finding is supported by the decrease of the amplitude of these components with increasing distance from the endplate region. Maximal effects on K conductance attainable with 3,4-DAP could still be potentiated by TEA, indicating the presence of at least two distinct sets of K channels. The prolonged positive potential induced by TEA and 3,4-DAP consisted of a fast and slow component, both of which can be attributed to Ca conductances with different characteristics. The fast positive signal component is attributed to the voltage-dependent Ca channel, responsible for the initiation of transmitter release. Its amplitude and duration depend on extracellular Ca2+ -concentration. The fast component is still present when Ca2+ is substituted by Sr2+ or Ba2+.(ABSTRACT TRUNCATED AT 250 WORDS)

Profiles of evoked release along the length of frog motor nerve terminals

In order to determine the relative probability of evoked transmitter release from different parts of frog motor nerve terminals, a technique has been developed in which single quantum end-plate potentials (e.p.p.s) are recorded by two intracellular electrodes, located at opposite ends of identified junctions. The log of the ratio of the amplitudes recorded simultaneously at the two electrodes is a linear function of the distance of the site of origin of the event from each of the two electrodes. Using online computer data acquisition and analysis, and current pulses at known locations for spatial calibration, it is possible to localize the site of single quantum e.p.p.s to within +/- 10-20 micron. Using the frog cutaneous pectoris neuromuscular preparation and a low calcium, high magnesium Ringer solution to ensure mostly single quantum events and failures, several thousand responses were recorded from each junction, allowing construction of a profile of the numbers of single quantum events arising from each portion of the junction. By comparison of junctional morphology and release profiles, it is possible to construct a probability of release per unit length profile for the entire junction. This technique has several advantages over localization of release events by measurements of extracellular synaptic currents. It was found that, for most junctions, the central 60-90% of the terminal exhibited relatively uniform probability of release, with highest levels typically near the point where the axon first contacted the muscle fibre, or in regions with many short terminal branches. However, no instances have been found in which a small region of terminal (10% or less) showed extraordinarily high release levels (30-50% of the total release from the junction). Characteristically, but not invariably, there is reduced release near the ends of terminal branches, especially the longer branches, where release per unit length could be as little as 5-10% of that in proximal portions. Some junctions had large regions of terminal that released very little transmitter. These also showed multiple myelineated axonal inputs, and may have been polyneuronally innervated junctions in which one of the inputs was much weaker than the other.

Control of quantal transmitter release at frog's motor nerve terminals. I. Dependence on amplitude and duration of depolarization

Motor terminals on the cutaneous pectoris muscle of the frog were depolarized by current pulses through the recording macro-patch-clamp electrode and the resulting quantal release was measured (excitation blocked with TTX). Above a threshold release increased very steeply with depolarization until saturation was approached. The dependence of release on duration of depolarization was even steeper: doubling pulse duration often produced more than 100-fold release ('early facilitation'). Distributions of delays of quantal release after the depolarization pulse were determined for wide ranges of depolarizations and pulse durations. The shape of these distributions was little affected by large changes in average release; increasing the temperature from 0 degrees C to 10 degrees C about halved the time scale of the distributions. Lengthening the depolarization from 0.5 to 6 ms produced a 'latency shift': the distributions of delays were shifted by almost the increase in pulse duration. At 5-6 ms pulse duration a few releases occurred during the final millisecond of the pulse. It is suggested that the time course of the phasic release is not controlled by the time course of changes in intracellular calcium concentration, but by an activator which is produced about proportional to supra-threshold pulse amplitude and duration, and that this activator effects release with a cooperativity of 6-7. An additional depolarization produced repressor is responsible for the minimum delay.

Excitability and depolarization-release characteristics of excitatory nerve terminals in a tail muscle of spiny lobster

In the deep abdominal L1-extensor muscle of the spiny lobster (Panulirus penicillatus) quantal excitatory postsynaptic currents (EPSCs) were recorded through macro-patch-clamp electrodes. Release of transmitter quanta from terminals was also elicited by depolarizing current pulses given through the recording electrode. The majority of terminals were excitable: on increasing the depolarization pulses, release was triggered at a threshold in an all-or-nothing manner. If excitation was blocked by tetrodotoxin (TTX), release was graded with depolarization reaching the amplitude of the all-or-nothing response at pulse amplitudes several times higher than the former threshold level. Some inexcitable terminals were also found: in these, release was graded for increasing depolarization pulses, and TTX did not alter the depolarization-release relation. Among the other types of terminals studied with the same technique, the proportion of excitable terminals in this lobster tail muscle is higher than in the crayfish opener and lower than in the frog's cutaneous pectoris muscle. The contribution of the increase in intraterminal Ca concentration to the control of release was estimated using facilitation of a test EPSC as an indicator of Ca inflow during a preceding depolarization pulse. This facilitation was found to have a maximum at a certain pulse amplitude, PF, and to decline for larger depolarizations. Release, however, rose considerably for depolarizations larger than those effected at PF. It is concluded that, like in crayfish and frog motor terminals, release is controlled directly by depolarization in addition to the control by Ca-inflow.

Presynaptic currents in frog motor endings

Membrane currents were recorded from non-myelinated frog endings by external electrodes. Changes in shape of the signals recorded at varying distances from the myelin end could be explained by assuming a non uniform distribution of Na and K channels along the presynaptic terminal. Specific channel blocking agents revealed that Na channels are present in highest density in the first half of each terminal branch and at almost undetectable levels near the extreme end, while K channels show a more widespread distribution with higher density at medial parts. Suppression of K conductance revealed Ca current which was seen as outward current near the myelin end.

Transmitter release triggered by a local depolarization in motor nerve terminals of the frog: role of calcium entry and of depolarization

Quantal synaptic currents (EPSCs) were elicited at neuromuscular junctions of frogs, applying current pulses through the recording current-clamp electrode. Facilitation of a test-EPSC by a preceding EPSC of variable amplitude was determined. This facilitation after a prepulse and release during the prepulse were found to have different dependences on depolarizing current amplitude. In addition, if intraterminal calcium [( Ca]i) was raised by a train of EPSCs, small depolarizations with little additional Ca entry elicited release which depended strongly on pulse amplitude. It is concluded that, in addition to [Ca]i, depolarization of the terminal directly controls quantal release. This depolarization dependence of release is shown to be the probable cause for termination of release after a large Ca entry.

Graded or all-or-nothing release of transmitter quanta by local depolarizations of nerve terminals on crayfish muscle?

In opener muscles of the first walking leg of 3 species of crayfish, quantal synaptic currents were recorded focally at synaptic spots by means of a macro-patch-clamp electrode. Proximal stimulation of the motor axons elicited excitatory postsynaptic currents (nEPSCs). In addition, current pulses through the recording electrode depolarizing the nerve terminal elicited similar synaptic release (pEPSCs). Artefact waveforms generated in the recording electrode after a pulse were compensated by a special circuit, allowing the pEPSC to be recorded from 0.3 to 1.5 ms after the pulse. In all terminals identified by recording nEPSCs, pEPSCs were also elicited, with a threshold pulse amplitude between -0.1 and -2 microA at 2 ms pulse duration. Most of the investigated terminals showed graded pEPSCs to rising amplitudes and durations of depolarizing pulses, and no effect of tetrodotoxin (TTX) on the pEPSCs. In these inexcitable terminals pEPSCs and nEPSCs showed mutual facilitation, with no signs of refractoriness for intervals as short at 3 ms. Some excitable terminals were found also: in these the amplitude of the pEPSC rose very steeply in an approximately all-or-nothing response on passing a threshold, while application of TTX reduced this response to one similar to that of inexcitable terminals. However, stimulation of such excitable terminals did not lead to antidromic conduction of action potentials into the main axon. In both inexcitable and excitable terminals, approximately the product of suprathreshold pulse amplitude and pulse duration determined the rate of release. The dependence of this response on pulse amplitude showed characteristic differences in proximal and distal synapses. The maximal double-logarithmic slope of this relation (sD) was 3.3 on the average in proximal synapses, while for distal synapses the average sD was 6.3. Further, in proximal synapses the nEPSC reached on average 86% of the maximum pEPSC, while the nEPSC in distal synapses amounted to only 5% of the maximum pEPSC. Therefore, the point of block of conduction in the terminal branch seems to lie father from the terminal in distal than in proximal synapses.

Transmitter release by graded local depolarization of presynaptic nerve terminals at the crayfish neuromuscular junction

Synaptic currents were recorded at single nerve terminals on the crayfish opener muscle by means of a patch-clamp electrode. Current pulses depolarizing the terminal were applied through the electrode which caused release of transmitter quanta. Such 'pulse-elicited excitatory postsynaptic currents' (pEPSCs) were not affected by the presence of tetrodotoxin, and no antidromic action potentials were detected in the motor nerve fiber after terminal depolarizations eliciting maximal pEPSCs. The amplitude of pEPSCs was graded in a wide range depending on amplitude and duration of the pulse, with different quantitative relationships for 'fast' and 'slow' synapses. It appears that these nerve terminals are inexcitable and are depolarized by the electronic spread of the motor nerve action potential.

Facilitation and impulse propagation failure at the frog neuromuscular junction

Exposure of frog neuromuscular junctions to solutions which contain a high concentration of calcium ions produces failure of neuromuscular transmission. This failure of transmission is abrupt and usually complete. However, some terminals produce small end-plate potentials even after the exposure to a high concentration of calcium ions. A second stimulus to the nerve can overcome the block of neuromuscular transmission if the interval between the stimuli is less than a critical value. The size of the end-plate potential is almost independent of the interstimulus interval if the latter is less than the critical value but more than the refractory period. The depth of this neuromuscular block is affected by temperature, potassium ions, osmotic pressure, cobalt ions, and prior high frequency stimulation of the nerve. Neuromuscular transmission failure coincides with failure of the nerve action potential (NAP) to invade the terminal. Prior to propagation failure, the second extracellularly recorded NAP is smaller, but is conducted faster than the first NAP. The relevance of these findings to the facilitation of transmitter release seen in solutions of normal divalent ion content is discussed.

Presynaptic currents in mouse motor endings

1. We used external electrodes placed under precise visual control on motor endings of the mouse to record electrical activity promoted by nerve stimulation.2. Three types of wave form have been observed in relation to well-defined electrode emplacements: (i) at the transition between myelinated and non-myelinated parts of the axon, the wave form consists of two negative deflexions preceded by a small positivity (preterminal response), (ii) at the main part of the terminal branches, we obtained a two component positive wave form (terminal response) and (iii) electrode positions in a narrow area between the former and the latter yielded triphasic (positive-negative-positive) wave forms (intermediate responses).3. Since these responses could not be readily interpreted in terms of classical description of membrane currents associated with propagating action potentials, we used specific channel blocking agents to identify wave form components.4. Bath application of tetraethylammonium or aminopyridines, or, better, a combination of both, suppressed delayed positive deflexions of terminal and intermediate responses and the late negative component of preterminal responses. Local inophoretic drug application showed that K channels are present only at the terminal part of the endings. K(+) outflux promotes a local circuit whose sink is located at the preterminal part where it generates the late negative deflexion of the preterminal response.5. Local application of tetrodotoxin suppressed the first negative component of preterminal responses but failed to affect electrical activity at the terminal part of the endings. This indicates that Na channels, and, therefore, action potential generation, are restricted to the preterminal part.6. Suppression of K conductance revealed a slow inward current at the terminal part of the endings which could be identified as a Ca current. Ba(2+) and Sr(2+) could substitute for Ca(2+) as inward current carriers.7. Activation of spatially separated Na channels, on one side, and of K and Ca channels, on the other, generated ionic currents and separated local circuit currents which flow between preterminal and terminal parts (and vice versa). Thus, the signals recorded at each point of motor endings correspond to the sum of ionic and passive currents entering (or leaving) the membrane at that point.8. The present results represent a further example of heterogeneity of axonal membrane.

Changes in miniature endplate potential frequency during repetitive nerve stimulation in the presence of Ca2+, Ba2+, and Sr2+ at the frog neuromuscular junction

Miniature endplate potentials (MEPPs) were recorded from frog sartorious neuromuscular junctions under conditions of reduced quantal contents to study the effect of repetitive nerve stimulation on asynchronous (tonic) quantal transmitter release. MEPP frequency increased during repetitive stimulation and then decayed back to the control level after the conditioning trains. The decay of the increased MEPP frequency after 100-to 200-impulse conditioning trains can be described by four components that decayed exponentially with time constants of about 50 ms, 500 ms, 7 s, and 80 s. These time constants are similar to those for the decay of stimulation-induced changes in synchronous (phasic) transmitter release, as measured by endplate potential (EPP) amplitudes, corresponding, respectively, to the first and second components of facilitation, augmentation, and potentiation. The addition of small amounts of Ca2+ or Ba2+ to the Ca2+-containing bathing solution, or the replacement of Ca2+ with Sr2+, led to a greater increase in the stimulation-induced increases in MEPP frequency. The Sr-induced increase in MEPP frequency was associated with an increase in the second component of facilitation of MEPP frequency; the Ba-induced increase with an increase in augmentation. These effects of Sr2+ and Ba2+ on stimulation-induced changes in MEPP frequency are similar to the effects of these ions on stimulation-induced changes in EPP amplitude. These ionic similarities and the similar kinetics of decay suggest that stimulation induced changes in MEPP frequency and EPP amplitude have some similar underlying mechanisms. Calculations are presented which show that a fourth power residual calcium model for stimulation-induced changes in transmitter release cannot readily account for the observation that stimulation-induced changes in MEPP frequency and EPP amplitude have similar time-courses.

A study of tetanic and post-tetanic potentiation of miniature end-plate potentials at the frog neuromuscular junction

1. The involvement of calcium sodium, potassium and magnesium in tetanic and post-tetanic potentiation of miniature end-plate potential frequency was examined at the frog neuromuscular junction using conventional electrophysiological techniques. 2. Tetanic potentiation is larger in calcium containing solutions, than in solutions which generate reversed electrochemical gradient for calcium during nerve activity. 3. Tetanic potentiation increases with stimulation frequency and duration, under both inward and reversed electrochemical gradient for calcium conditions. This indicates that factors, other than calcium entry, participate in tetanic potentiation. 4. Addition of the potassium conductance blocking agent, 3-aminopyridine (5 mM), increases tetanic potentiation in calcium containing media, while depressing it under reversed calcium gradient. 5. Electronic depolarization of the nerve terminal in tetrodotoxin-containing Ringer solution, produces tetanic potentiation under inward gradient, but fails to do so under reversed gradient. This indicates that the entry of sodium ions participates in the generation of tetanic potentiation. 6. Addition of magnesium ions suppresses tetanic potentiation in calcium containing solution, but increases tetanic potentiation under reversed gradient. 7. The results are explained by the hypothesis that calcium entry and intracellular calcium translocation participate in the generation of tetanic potentiation. 8. Both the fast and the slow components (augmentation and potentiation respectively) of post-tetanic potentiation increase in duration, with increase in the tetanic stimulation rate. 9. The decay of post-tetanic potentiation increases: when [Ca]o is elevated by ionophoretic application during the decay phase only, when ouabain is present in the medium or when [Mg]o is elevated. These finding suggest that calcium, sodium and possibly magnesium take part in post-tetanic potentiation.

Paired-pulse and frequency facilitation in the CA1 region of the in vitro rat hippocampus

1. Several types of facilitation of evoked synaptic responses were investigated in the CA1 region of the in vitro rat hippocampus. Homosynaptic paired-pulse facilitation and heterosynaptic frequency facilitation were characterized and found to be differentiable processes on the basis of several characteristics.2. Paired-pulse facilitation, which occurs when the same input is stimulated twice in rapid succession, is manifested as an increase in both the extracellularly recorded population spike and the field e.p.s.p., and is specific to the set of afferents excited by the first impulse. Responses to other excitatory afferents show no facilitation by a heterosynaptic conditioning pulse.3. At intervals less than 200 msec, the degree of facilitation produced by a preceding impulse appears to decline as a first order exponential function of time. Facilitation is increased by lowering calcium or raising magnesium concentrations in the bathing medium, with no apparent change in the time constant of the decay process.4. The phenomenon that has sometimes been termed frequency facilitation, and which occurs during the early phase of repetitive stimulation, appears to be an extension of paired-pulse facilitation. It is seen as an increase in amplitude of both the e.p.s.p. and population spike in response to stimulation of homosynaptic inputs, can be predicted with fair accuracy by assuming that the residual paired-pulse facilitation produced by each impulse adds linearly with that from previous impulses, and is affected by calcium and magnesium ions in the same manner as is paired-pulse facilitation. These two types of facilitation, which apparently share a common mechanism, are termed synaptic or primary facilitation.5. Another type of facilitation, which we suggest might more properly be called frequency facilitation, develops slowly during the course of repetitive stimulation. It is the result of an increase in cell firing in response to any excitatory input, either homo- or heterosynaptic, at time points at which the field e.p.s.p. is typically depressed.6. Increases in the potassium concentration of the perfusion medium produce effects similar to those observed with frequency facilitation; stimulation-evoked increases in the extracellular concentration of this ion are hypothesized to underlie this type of generalized facilitation.

Intra- and extracellular measurements of frog neuromuscular transmission upon stretch of the muscle at different stimulus frequencies

Flexible intracellular micro-electrodes were used to study the effect of changes in muscle length on the end-plate potential in the isolated m. cutaneus pectoris for different frequencies of stimulation (1/60-5Hz). A 20% step-wise increase in muscle length within the physiological range increases the end-plate potential immediately by about 50% (range 0-120%) at all frequencies tested. At stimulus frequencies lower than 1/5 Hz this increase is sustained during a period of 15 min stretch. At 1 Hz, however, the initial increase in the end-plate potential amplitude on the average declines within a few minutes to a steady-state value about 35% higher than the steady-state end-plate potential before stretch. At 5 Hz, the initial amplitude increase is followed by a decline of about 15 min duration and the final amplitude is not increased in comparison with the pre-stretch amplitude. The amplitude of the compound muscle action potential of the gastrocnemius muscle with intact circulation shows a similar time dependent increase upon stretch at different stimulus frequencies. It is concluded that stretch of a frog muscle gives both an immediate and a sustained increase in transmitter release from the nerve terminals during prolonged stimulation at frequencies up to about 5 Hz. This effect of stretch on transmitter release can improve in vivo neuromuscular impulse transmission.

Changes in the structure of neuromuscular junctions caused by variations in osmotic pressure

Neuromuscular junctions of the frog, Rana pipiens, were examined for structural modifications produced by exposure to increased and reduced osmotic pressure (pi). Preparations exposed to increased pi for varying lengths of time were fixed with either OSO4-Veronal with and without calcium, glutaraldehyde-phosphate, or glutaraldehyde-formaldehyde-phosphate as primary fixatives. The greatest difference between the fixatives was seen in preparations exposed to increased pi for 5 min, corresponding to the time when miniature endplate potential frequency is highest. The 5-min OSO4 calcium-free preparations appeared comparatively normal, while those fixed with OSO4 and 2 mM CaCl2 or aldehyde-phosphate had wide infoldings of the presynaptic membrane and a reduced number of synaptic vesicles. Aldehyde-phosphate had the same effect on mouse diaphragm. Another series of frog preparations were conditioned to elevated pi and then returned to normal Ringer's for varying times before fixation in OSO4-phosphate. Preparations fixed 2 min after their return to normal Ringer's showed marked disruption of the presynaptic membrane as well as apparently rupturing vesicles. If fixed after 10 min, terminals were depleted of vesicles although the presynaptic membrane had returned to its normal position and appearance.

Crayfish neuromuscular facilitation activated by constant presynaptic action potentials and depolarizing pulses

1. Experiments were conducted to test the hypothesis that facilitation of transmitter release in response to repetitive stimulation of the exciter motor axon to the crayfish claw opener muscle is due to an increase in the amplitude or duration of the action potential in presynaptic terminals. No consistent changes were found in the nerve terminal potential (n.t.p.) recorded extracellularly at synaptic sites on the surface of muscle fibres.2. Apparent changes in n.t.p. are attributed to three causes.(i) Some recordings are shown to be contaminated by non-specific muscle responses which grow during facilitation.(ii) Some averaged n.t.p.s exhibit opposite changes in amplitude and duration which suggest a change in the synchrony of presynaptic nerve impulses at different frequencies.(iii) Some changes in n.t.p. are blocked by gamma-methyl glutamate, an antagonist of the post-synaptic receptor, which suggests that these changes are caused by small muscle movements.3. The only change in n.t.p. believed to represent an actual change in the intracellular signal is a reduction in n.t.p. amplitude to the second of two stimuli separated by a brief interval.4. Tetra-ethyl ammonium ions increase synaptic transmission about 20% and prolong the n.t.p. about 15%. This result suggests that an increase in n.t.p. large enough to increase transmission by the several hundred per cent occurring during facilitation would be detected.5. The nerve terminals are electrically excitable, and most synaptic sites have a diphasic or triphasic n.t.p., which suggests that the motor neurone terminals are actively invaded by nerve impulses.6. When nerve impulses are blocked in tetrodotoxin, depolarization of nerve terminals increases the frequency of miniature excitatory junctional potentials (e.j.p.s), and a phasic e.j.p. can be evoked by large, brief depolarizing pulses. Responses to repetitive or paired depolarizations of constant amplitude and duration exhibit a facilitation similar to that of e.j.p.s evoked by nerve impulses.7. It is concluded that facilitation in the crayfish claw opener is not due to a change in the presynaptic action potential, but is due to some change at a later step in the depolarization-secretion process.

Excitability changes in crayfish motor neurone terminals

1. Changes in the post-activation excitability of crayfish motor nerve terminals were used to measure afterpotentials that might be related to facilitation of transmitter release.2. The refractory period is followed by a period of supernormal excitability in which the threshold of nerve terminals drops to about 70% of its pre-activation level at about 15 msec following an impulse. The threshold returns exponentially to its pre-activation level with a time constant of about 25 msec at 13 degrees C. Such a supernormal excitability is rarely seen in pre-terminal nerve branches or in the main axon.3. Following a brief high-frequency tetanus the peak of the supernormal excitability is greater than that following a single impulse. At low temperature this peak is reduced and delayed, and the decay rate of the supernormal excitability is prolonged with a Q(10) of about 2.5.4. Depolarization of nerve terminals decreases, and hyperpolarization increases, the magnitude of the post-activation supernormal excitability.5. The magnitude of the supernormal excitability depends on the external potassium concentration, but not on sodium. In low calcium the peak supernormal excitability is often reduced. High calcium concentration and manganese ions have no effect, but cobalt abolishes the supernormal excitability, and its effects are only slightly reversible. Both cobalt and manganese reversibly block neuromuscular transmission.6. Strophanthidin has no effect on the post-activation supernormal excitability, but proteolytic enzymes reduce or abolish it, and hyperosmotic solutions also affect it.7. It is suggested that the action potential is followed by a depolarizing afterpotential in nerve terminals which is caused by a transient increase in the potassium concentration around the terminals. There is no evidence that afterpotentials in nerve terminals are related to facilitation in any way.

The density of acetylcholine receptors and their sensitivity in the postsynaptic membrane of muscle endplates

In various skeletal muscles, the mean density of acetylcholine receptors in the muscle postsynaptic membrane is constant at about 8700 per mum(2), even though the overall size of an endplate ranged from 400 mum(2) to 1300 mum(2) in these muscles. This measurement was by electron microscope autoradiography of alpha-[(3)H]bungarotoxin binding sites; only one-half of these, however, appear to be true active centers of the acetylcholine receptor. The highest density of these receptors is on the juxtaneuronal regions of the postsynaptic membrane, and their density in the depths of the fold is less than one quarter of that at the tips. A maximum sensitivity to externally applied acetylcholine, about 3000-5000 mV/nC, is found in diverse types of endplates when truly focal recording is achieved. This acetylcholine sensitivity appears to be determined by the local density of receptors in the membrane, and not by their total number at the endplate. A quantal efficiency term is also disclosed. The maximal sensitivity per molecule obtainable by microiontophoresis of acetylcholine is 5-10% of that operative when a quantum reacts. When acetylcholine is released from a vesicle, in contrast to its application from outside, geometric factors are more favorable. Consideration of the local packing density, acetylcholine molecule numbers, and the current flow when one quantum of acetylcholine interacts at the membrane suggests that one, or possibly two, activated receptor active centers are linked to one open gate of the ionic conductance modulator.

On facilitation of transmitter release at the toad neuromuscular junction

1. The time dependence of the increase in amplitude (facilitation) of a second end-plate potential (e.p.p.) elicited within 10-100 msec of a preceding e.p.p. was examined at neuromuscular junctions in sartorius muscles of toads. Facilitation was defined by two characteristics, initial facilitation and the time constant of its exponential decay.2. The time constant of decay of facilitation was longer at lower temperatures and the Q(10) was 4.3 in the range 10-25 degrees C. There was no significant effect of temperature on initial facilitation.3. Ouabain (10(-4)-10(-3)M), lithium substitution for sodium, sodium azide (5 mM) and N-ethylmaleimide (NEM, 0.1 mM) initially had no effect on initial facilitation or the decay of facilitation. After some time, they all caused a longer time constant of decay of facilitation and a depression of initial facilitation.4. It was concluded that the decay of facilitation is not directly dependent on active transport of sodium ions, calcium efflux, ATP-dependent movements of calcium or mitochondrial uptake of calcium following an action potential.5. Ouabain, lithium, sodium azide, and NEM all caused an increase in transmitter release. This effect, and the late effects on facilitation, were thought to be due to an increase in intracellular calcium concentration in nerve terminals.6. No relationship was found between the quantal content of e.p.p.s (range, 0.8-100) and initial facilitation, or the time constant of decay of facilitation.7. Substitution of strontium for calcium ions caused a marked prolongation of the time constant of decay of facilitation, and a depression of initial facilitation.8. The results were consistent with the hypothesis that the time constant of decay of facilitation is related to the rate of disappearance of an ;active' complex of calcium (CaA) which, of itself, is not sufficient for transmitter release. It is suggested that an action potential produces CaA which decays with the time constant of facilitation and CaS, a short-life complex of calcium which decays with the time constant of the phasic release of transmitter. The release of transmitter is proportional to some function of [CaA] and [CaS].

An analysis of the role of calcium in facilitation at the frog neuromuscular junction

1. Under appropriate conditions stimulation of the neuromuscular junction by a single impulse or a brief train causes subsequent impulses to release increased amounts of transmitter. It has been proposed that this facilitation of transmitter release is due to calcium which remains on release sites following the conditioning stimuli. This residual calcium hypothesis is examined in frog cutaneous pectoris muscle in the present study.2. The second component of facilitation is shown to depend on the amount of calcium present during tetanization as required by the residual calcium hypothesis.3. The quantitative behaviour of the facilitation accompanying tetani of a number of frequencies and durations is found to be consistent with the residual calcium hypothesis.4. Quantitative analysis of facilitation leads to a description of the time course of removal of calcium from release sites which is discussed.

The effect of tetanic and post-tetanic potentiation on facilitation of transmitter release at the frog neuromuscular junction

1. End-plate potentials (e.p.p.s) were recorded from frog neuromuscular junctions blocked with high Mg and/or low Ca.2. Estimates of f(t), the facilitation contributed by each impulse, were obtained during and following repetitive stimulation from the incremental change in e.p.p. amplitudes following step changes in the stimulation rate during the conditioning and testing trains.3. Estimates of f(t) increased during the conditioning stimulation and returned to control in the post-tetanic period. This increase in f(t) was proportional to the magnitude of tetanic or post-tetanic potentiation (PTP) present.4. These results are described by: [Formula: see text] where h(t)/h(c) is the e.p.p. amplitude at time t expressed in terms of the control, P(t) is potentiation, F(t) is facilitation and 1 is the base level of transmitter release. Thus, potentiation has a multiplicative (gain) effect on facilitation and the base level of transmitter release.5. PTP was present immediately following the conditioning train. However, if depression occurred during the conditioning train, PTP developed after a delay.6. It is suggested that facilitation and potentiation represent increases in two independent factors which act jointly to increase the probability of transmitter release.

The effect of repetitive stimulation on facilitation of transmitter release at the frog neuromuscular junction

1. End-plate potentials (e.p.p.s) were recorded from frog neuromuscular junctions blocked with high Mg and/or low Ca to characterize the processes underlying increased transmitter release during repetitive stimulation.2. There was a progressive increase in the amplitude of successive e.p.p.s during repetitive stimulation. Increasing the frequency or duration of stimulation increased this facilitation of e.p.p. amplitudes. Facilitation is defined as the fractional increase in amplitude of a test e.p.p. over a control.3. By assuming that each impulse in a train contributes an identical increment of facilitation that sums linearly with the facilitation contributed by the previous impulses, estimates of the facilitation contributed by a single impulse, f(t), were made from the incremental increase in e.p.p. amplitudes during repetitive stimulation. The average value of f(t) contributed by the first impulse in the train during stimulation at 20/sec is given by f(t) = 0.8 e(-t/50) + 0.12 e (-t/300) + 0.025 e(-t/3000),where t is in msec. The first two terms in this equation were independent of the stimulation rate used to determine f(t) while the coefficient of the third term was a function of the stimulation rate, decreasing 2 to 3 times when the stimulation rate was decreased from 20/sec to 1/sec.4. This linear facilitation model predicted growth of e.p.p. amplitudes during the first several hundred msec of repetitive stimulation. Thereafter, e.p.p. amplitudes were typically facilitated more than predicted by the linear model.5. Several new methods are presented which can be used to obtain estimates of the magnitude and time course of facilitation contributed by specific impulses during repetitive stimulation.6. It is found that the value of short-term f(t) in the tested range of 25-300 msec progressively increases during repetitive stimulation while its time course of decay remains unchanged. After 9 sec of stimulation at 20/sec, the short-term f(t) increased to 1.4 times control.7. The increase in short-term f(t) was independent of whether it was determined from a step increase or decrease in total facilitation, excluding the possibility that the observed increase in short-term f(t) resulted from a change in the rate of decay of facilitation.8. It is suggested with supporting data from the following paper (Magleby, 1973) that each impulse contributes two types of facilitation that are responsible for the growth of e.p.p.s during repetitive stimulation: a short-term facilitation with linear summation properties described by the first two terms in the expression in paragraph 3 and a long-term cumulative facilitation approximated by the third term. The long-term facilitation is expressed as an increase in both the short-term facilitation and in the base level of transmitter release. The relative contribution of these two expressions of the long-term facilitation to the third term is a function of the stimulation rate and is given by the ratio of facilitation to the base level of transmitter release.

Calcium and facilitation at two classes of crustacean neuromuscular synapses

The closer muscle of the crab, Chionoecetes, has at least two classes of excitatory neuromuscular synapses. In one class of synapses an action potential depolarizing the synaptic region releases much more transmitter if it has been preceded recently by another action potential. The other class of synapses shows this property, called facilitation, to a far lesser extent. Immediately after one conditioning stimulus the level of facilitation is similar in both classes. The rate of the ensuing decay of the facilitation is the critical factor differentiating the two classes of synapses. The relationship between external Ca(++) concentration and transmitter release is similar for both classes of synapses. The slope of a double logarithmic plot of this relationship varies from 3.1 between 5 and 10 mM Ca(++) to 0.9 between 30 and 40 mM Ca(++). Facilitation does not significantly change when tested in external Ca(++) concentrations ranging from 7 to 30 mM. The extracellularly recorded nerve terminal action potential does not increase in amplitude during facilitation. The results suggest that the mechanism of synaptic facilitation is similar for both classes of synapses and occurs after the stage in transmitter release involving Ca(++).

Changes in the fine structure of the neuromuscular junction of the frog caused by black widow spider venom

Application of black widow spider venom to the neuromuscular junction of the frog causes an increase in the frequency of miniature end-plate potentials (min.e.p.p.) and a reduction in the number of synaptic vesicles in the nerve terminal. Shortly after the increase in min.e.p.p. frequency, the presynaptic membrane of the nerve terminal has either infolded or "lifted." Examination of these infoldings or lifts reveals synaptic vesicles in various stages of fusion with the presynaptic membrane. After the supply of synaptic vesicles has been exhausted, the presynaptic membrane returns to its original position directly opposite the end-plate membrane. The terminal contains all of its usual components with the exception of the synaptic vesicles. The only other alteration of the structures making up the neuromuscular junction occurs in the axon leading to the terminal. Instead of completely filling out its Schwann sheath, the axon has pulled away and its axoplasm appears to be denser than the control. The relation of these events to the vesicle hypothesis is discussed.