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Neurotransmitter release from the basolateral surface of auditory and vestibular hair cells is mediated by Ca(2+) influx through voltage-gated Ca(2+) channels. Co-localization of large-conductance Ca(2+)-activated K(+) (BK) channels at the active zones of these cells affords them with an optimal location to act as reporters of the Ca(2+) concentration changes at active zones of transmitter release. In this report we use BK channels in frog (Rana pipiens) hair cells to monitor dynamic changes in intracellular Ca(2+) concentration during transient influxes of Ca(2+), showing that BK current magnitude and delay to onset are correlated with the rate and duration of Ca(2+) entry through Ca(2+) channels. We also show that BK channels exhibit a much higher Ca(2+) binding affinity in the open state than in the closed state.

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1. Simultaneous pre- and postsynaptic patch recordings were obtained from the varicosity synapses formed by Xenopus motoneurons on muscle cells in embryonic cultures, in order to elucidate the contribution of N- and L-type Ca(2+) channels to the varicosity Ca(2+) current (I(Ca)) and evoked transmitter release. 2. Although N-type channels are predominant in the varicosities and generally thought to be responsible for all evoked release, in most synapses a fraction of I(Ca) and release could be reversibly blocked by the L-type channel antagonist nifedipine, and enhanced by the agonist Bay K8644. Up to 50 % (mean, 21 %) of the I(Ca) evoked by a voltage clamp waveform mimicking a normal presynaptic action potential (APWF) is composed of L-type current. 3. Surprisingly, the nifedipine-sensitive (L) channels activated more rapidly (time-constant, 0.46 ms at +30 mV) than the nifedipine-insensitive (N) channels (time constant, 1.42 ms). Thus the L-type current would play a disproportionate role in the I(Ca) linked to a normal action potential. 4. The relationship between I(Ca) and release was the same for nifedipine-sensitive and -resistant components. The N- and L-components of I(Ca) are thus equally potent in evoking release. This may represent an immature stage before N-type channels become predominant. 5. Replacing Ca(2+) in the medium with Ba(2+) strongly enhanced the L-type component, suggesting that L-type channels may be inactivated at Ca(2+) levels close to those at rest. 6. We speculate that populations of L-type channels in different parts of the neuron may be recruited or inactivated by fluctuations of the cytosolic Ca(2+) concentration within the physiological range.

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Hyperosmotic solutions cause markedly enhanced spontaneous quantal release of neurotransmitter from many nerve terminals. The mechanism of this enhancement is unknown. We have investigated this phenomenon at the frog neuromuscular junction with the aim of determining the degree to which it resembles the modulation of release by stretch, which has been shown to be mediated by mechanical tension on integrins. The hypertonicity enhancement, like the stretch effect, does not require Ca2+ influx or release from internal stores, although internal release may contribute to the effect. The hypertonicity effect is sharply reduced (but not eliminated) by peptides containing the RGD sequence, which compete with native ligands for integrin bonds. There is co-variance in the magnitude of the stretch and osmotic effects; that is, individual terminals exhibiting a large stretch effect also show strong enhancement by hypertonicity, and vice versa. The stretch and osmotic enhancements also can partially occlude each other. There remain some clear-cut differences between osmotic and stretch forms of modulation: the larger range of enhancement by hypertonic solutions, the relative lack of effect of osmolarity on evoked release, and the reported higher temperature sensitivity of osmotic enhancement. Nevertheless, our data strongly implicate integrins in a significant fraction of the osmotic enhancement, possibly acting via the same mechanism as stretch modulation.

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Using Xenopus nerve-muscle co-cultures, we have examined the contribution of calcium-activated potassium (K(Ca)) channels to the regulation of transmitter release evoked by single action potentials. The presynaptic varicosities that form on muscle cells in these cultures were studied directly using patch-clamp recording techniques. In these developing synapses, blockade of K(Ca) channels with iberiotoxin or charybdotoxin decreased transmitter release by an average of 35%. This effect would be expected to be caused by changes in the late phases of action potential repolarization. We hypothesize that these changes are due to a reduction in the driving force for calcium that is normally enhanced by the local hyperpolarization at the active zone caused by potassium current through the K(Ca) channels that co-localize with calcium channels. In support of this hypothesis, we have shown that when action potential waveforms were used as voltage-clamp commands to elicit calcium current in varicosities, peak calcium current was reduced only when these waveforms were broadened beginning when action potential repolarization was 20% complete. In contrast to peak calcium current, total calcium influx was consistently increased following action potential broadening. A model, based on previously reported properties of ion channels, faithfully reproduced predicted effects on action potential repolarization and calcium currents. From these data, we suggest that the large-conductance K(Ca) channels expressed at presynaptic varicosities regulate transmitter release magnitude during single action potentials by altering the rate of action potential repolarization, and thus the magnitude of peak calcium current.

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Neurotransmitter release during action potentials is thought to require transient, localized [Ca2+]i as high as hundreds of micromolar near presynaptic release sites. Most experimental attempts to characterize the magnitude and time course of these Ca2+ domains involve optical methods that sample large volumes, require washout of endogenous buffers and often affect Ca2+ kinetics and transmitter release. Endogenous calcium-activated potassium (KCa) channels colocalize with presynaptic Ca2+ channels in Xenopus nerve-muscle cultures. We used these channels to quantify the rapid, dynamic changes in [Ca2+]i at active zones during synaptic activity. Confirming Ca2+-domain predictions, these KCa channels revealed [Ca2+]i over 100 microM during synaptic activity and much faster buildup and decay of Ca2+ domains than shown using other techniques.

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Neurotransmitter release from different parts of frog motor nerve terminals is often non-uniform. There is a decrease in release efficacy from the distal regions of frog motor nerve terminal branches. Since release is thought to occur near the double arrays of large intramembranous particles that constitute the pre-synaptic active zones (AZs), we have examined quantitatively the proximal-distal distribution of AZ structure, using a novel freeze-fracture technique that produces replicas of large fractions of terminals, including the region of nerve entry. This enables us to know the proximal distal orientation of each branch. From 23 end-plates we have obtained fractures of 72 branches. For 27 of these branches we have obtained continuous fractures both greater than 25 microm in length and with sufficient information to determine their proximal distal polarity. Only a few of these branches showed a marked distal decrease in AZ length/unit length of terminal, while several junctions had short regions (5-10 microm), either proximally or distally, that exhibited amounts of AZ that were substantially greater or smaller than the mean value for that terminal branch. The terminal area, post-synaptic gutter width and nerve terminal width all exhibit some distal decline concomitant with the distal tapering of nerve terminal branches. AZ length tends to have the least decline compared to the other parameters. Thus, the vast majority of frog motor nerve terminal branches do not display a significant proximal-distal gradient in the amount of AZ structure / microm terminal length. The present data do not provide an obvious ultrastructural correlate for the distal decline in transmitter release that some authors have observed.

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The orderly arrays of intramembranous particles (IMPs) found in the p-face of freeze-fracture replicas of the frog neuromuscular junction ('active zones') are believed to be involved in transmitter release. Some or all of the particles represent voltage-dependent Ca2+ channels. Since there is a great heterogeneity in the amount of transmitter released by different frog motor nerve terminals we sought to determine whether active zone (AZ) structure displayed a similar heterogeneity by using a novel freeze-fracture procedure providing large, intact replicas containing significant portions of motor nerve terminals from the cutaneous pectoris muscle of the frog, Rana pipiens. Using only junctions in which more than 50 AZs or more than 50 microm of nerve terminal were included in the fractures, we measured AZ length, AZ intramembranous particle density, terminal width at each AZ, space between AZs, the angle of AZ orientation with respect to the longitudinal axis of the nerve terminal, exposed pre-synaptic nerve terminal surface area and a calculated value for mean AZ length per unit terminal length. The analysis led to the following conclusions. There is an approximate 5-fold range in mean AZ length/micrometre terminal length. Terminal width is a good predictor of AZ length. Particle density does not vary significantly within a given AZ, nor between AZs from the same or different junctions. The distance between AZs is not related to AZ length, i.e. shorter AZs are no more or less likely to be closer to the adjacent AZ. The probability of release from any AZ on action potential invasion is small. If most of the IMPs are Ca2+ channels, either the probability of channel opening or the efficacy of triggering release is very low or both. That the variability in release efficacy in different terminals is much greater than ultrastructural variability in terminals suggests that regulation of release is dominated by physiological processes that do not have obvious ultrastructural correlates. On the other hand, the apparent excess of AZ relative to the number of vesicles released indicates that the amount and variability in amount of AZ is important in ways that need to be elucidated.

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The understanding of neurotransmitter release at vertebrate synapses has been hampered by the paucity of preparations in which presynaptic ionic currents and postsynaptic responses can be monitored directly. We used cultured embryonic Xenopus neuromuscular junctions and simultaneous pre- and postsynaptic patch-clamp current-recording procedures to identify the major presynaptic conductances underlying the initiation of neurotransmitter release. Step depolarizations and action potential waveforms elicited Na and K currents along with Ca and Ca-activated K (KCa) currents. The onset of KCa current preceded the peak of the action potential. The predominantly omega-CgTX GVIA-sensitive Ca current occurred primarily during the falling phase, but there was also significant Ca2+ entry during the rising phase of the action potential. The postsynaptic current began a mean of 0.7 msec after the time of maximum rate of rise of the Ca current. omega-CgTX also blocked KCa currents and transmitter release during an action potential, suggesting that Ca and KCa channels are colocalized at presynaptic active zones. In double-ramp voltage-clamp experiments, KCa channel activation is enhanced during the second ramp. The 1 msec time constant of decay of enhancement with increasing interpulse interval may reflect the time course of either the deactivation of KCa channels or the diffusion/removal of Ca2+ from sites of neurotransmitter release after an action potential.

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Neurotransmitter release from frog motor nerve terminals is strongly modulated by change in muscle length. Over the physiological range, there is an approximately 10% increase in spontaneous and evoked release per 1% muscle stretch. Because many muscle fibers do not receive suprathreshold synaptic inputs at rest length, this stretch-induced enhancement of release constitutes a strong peripheral amplifier of the spinal stretch reflex. The stretch modulation of release is inhibited by peptides that block integrin binding of natural ligands. The modulation varies linearly with length, with a delay of no more than approximately 1-2 msec and is maintained constant at the new length. Moreover, the stretch modulation persists in a zero Ca2+ Ringer and, hence, is not dependent on Ca2+ influx through stretch activated channels. Eliminating transmembrane Ca2+ gradients and buffering intraterminal Ca2+ to approximately normal resting levels does not eliminate the modulation, suggesting that it is not the result of release of Ca2+ from internal stores. Finally, changes in temperature have no detectable effect on the kinetics of stretch-induced changes in endplate potential (EPP) amplitude or miniature EPP (mEPP) frequency. We conclude, therefore, that stretch does not act via second messenger pathways or a chemical modification of molecules involved in the release pathway. Instead, there is direct mechanical modulation of release. We postulate that tension on integrins in the presynaptic membrane is transduced mechanically into changes in the position or conformation of one or more molecules involved in neurotransmitter release, altering sensitivity to Ca2+ or the equilibrium for a critical reaction leading to vesicle fusion.

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Multielectrode recordings were used to identify and measure the axonal inputs to each end plate on contiguous surface fibers covering about 25% of the Xenopus pectoralis muscle in mature and developing animals. The mature innervation pattern was remarkably precise. Individual axons tended to innervate fibers of similar input resistance (R(in)) in compact motor units restricted to only a portion of the region studied. Motor units comprising fibers of similar R(in) overlapped mainly near their borders. Most fibers had two end plates. In more than 80% of these fibers, both end plates received input from the same axon. In 57%, this was the only input to both end plates. This implies a powerful mechanism for excluding or eliminating inputs from other axons. About 16% of the mature junctions showed focal polyneuronal innervation, with the weaker end plate potential component often less than 1 mV in noncurarized preparation. However, we have no evidence that the weaker inputs were being eliminated. During development, motor units became more compact, which was associated with synapse elimination; but from the earliest times studied, soon after metamorphosis when many fibers were adding second end plates, a majority of those that had two end plates were innervated at both sites by the same axon.

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We investigated the motor unit organization and precision of reinnervation in the Xenopus pectoralis muscle following different manipulations, including crush or section of the posterior pectoralis nerve, foreign nerve innervation, and crush coupled with activity modulation or block. Most fibers have two neuromuscular junctions, and multielectrode recordings were used to identify the axonal origin of all inputs to both junctions on most or all fibers covering about 25% of the muscle surface. Following simple nerve crush, a highly organized innervation pattern was restored, indistinguishable from the normal pattern, including selective innervation of fibers of similar input resistance (R(in)), compact motor unit organization, and high incidence of exclusive innervation of both end plates on each fiber by the same axon (distributed mononeuronal innervation, or a/a pattern). Initial reinnervation was equally precise when nerve conduction in the regenerating nerve was blocked by tetrodotoxin. More distant or repeated nerve crush or nerve section delayed and reduced the precision of reinnervation, but the majority of fibers still received input to both end plates by the same axon, often in combination with others. A foreign nerve, the pectoralis sternalis, which in its own muscle forms only single end plates, showed less precise reinnervation, but still had an incidence of a/a innervation far above chance. These data imply the expression and recognition of remarkably precise chemospecific cues even in mature animals, superimposed on which is a further refinement by synapse elimination, probably based on an activity-dependent process.

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Barium currents through voltage-gated calcium (Ca2+) channels were studied in the small-cell lung carcinoma cell line NCI-H345 using patch clamp techniques. Pharmacological dissection of whole-cell barium currents revealed that 23% of the current was sensitive to nitrendipine, 35% to omega-conotoxin GVIA, and between 10 and 39% to omega-Aga-IVA. This implies that these cells express L-, N-, and P-type calcium channels. Only large cells expressed current that was sensitive to omega-Aga-IVA. The size dependency of this P-type channel expression may reflect the cell cycle stage. Cell-attached recordings revealed three unitary conductances: 5 to 6 pS, 10 to 12 pS, and 20 to 23 pS. The largest conductance channel (20-23 pS) was sensitive to Bay K 8644 and is presumed to represent L-type calcium channels. The frequency of observing the medium conductance channel (10-12 pS) was reduced by exposure to omega-conotoxin GVIA and may represent N-type channels. Incubation of cells with Lambert-Eaton myasthenic syndrome IgG for 24 to 48 hours removed up to 71% of the whole-cell current. Incubation with control human IgG (normal or myasthenia gravis) had no effect. Lambert-Eaton myasthenic syndrome IgG did not selectively target one "presynaptic" type of calcium channel, but rather appeared to target many of the calcium channel types that are expressed on small-cell lung carcinoma cells.

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Transmitter release from frog motor nerve terminals occurs at specialized sites on the nerve terminal called active zones (AZs). We have used a low calcium (0.1 nM) saline treatment to disrupt AZ structure and correlated these changes with alterations in transmitter release from the nerve terminal. Exposure to 0.1 nM free calcium saline for 3 h caused many individual AZs to break into two or three pieces, apparently unorganized particles drifted free of the AZ array, and the normally ordered alignment of AZ particles was loosened. Despite these forms of disruption in AZ organization, physiological function remained remarkably normal. Although the size of the endplate potential recorded in response to a single nerve stimulus was little affected, paired-pulse facilitation and tetanic potentiation were significantly increased. Synaptic depression was not apparent during the tetanus, but was revealed following the cessation of the stimulation. The results are consistent with the hypothesis that 0.1 nM calcium treatment detached AZ segments from the anchoring molecules that normally hold these proteins in alignment with other synapse-specific molecules. We propose that the ordered AZ organization serves to bring the calcium channels that regulate transmitter release in close proximity to other proteins that are critical to the modulation of release, especially during periods of high frequency stimulation. We hypothesize that the drifting AZ segments, although capable of apparently normal transmitter release, may not be tightly coupled with the intracellular calcium handling proteins that normally restrict the time that calcium ions have to act on the transmitter release apparatus following each action potential.

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Neuromuscular connections have long served as models of synaptic structure and function. They also provide illuminating insights into the dynamic cell-cell interactions governing synaptogenesis, neuromuscular differentiation, and the maintenance of effective function. This paper reviews recent advances in our understanding of the regulatory and inductive interactions involved in motor axon pathfinding, target recognition, bidirectional control of gene expression during synapse formation, motoneuron cell death, terminal rearrangement, and the ongoing remodeling of synaptic number, structure, and function to adjust to growth and changes in use.

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The stretch of a frog muscle within the physiological range can more than double the spontaneous and evoked release of neurotransmitter from its motor nerve terminals. Here, stretch enhancement of release was suppressed by peptides containing the sequence arginine-glycine-aspartic acid (RGD), which blocks integrin binding. Integrin antibodies also inhibited the enhancement obtained by stretching. Stretch enhancement depended on intraterminal calcium derived both from external calcium and from internal stores. Muscle stretch thus might enhance the release of neurotransmitters either by elevating internal calcium concentrations or by increasing the sensitivity of transmitter release to calcium in the nerve terminal.

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1. Single acetylcholine receptor (AChR) channel openings, detected by the whole-cell patch clamp technique, were used to monitor quantal and non-quantal ACh release at synapses in 1- and 2-day-old co-cultures of Xenopus embryonic motoneurons and muscle cells. motoneuron growth cones in ways that presumably reflect muscle-nerve inductive influences and the development of neurotransmitter release mechanisms. 2. Miniature endplate currents (MEPCs) occurred at a mean frequency of approximately 0.6 s-1 with a skewed distribution and mean amplitude of about twenty channel openings. In addition, occasional brief episodes of rapid deviations in the baseline were observed in some cells, with mean amplitudes of 4-8 pA and durations of a few hundred milliseconds. However, these episodes did not closely resemble summated openings of AChR channels. Moreover, where tested, these episodes were not blocked by curare; and comparable episodes were seen in an uninnervated myocyte. Thus they appear not to reflect ACh release from the nerve terminal. 3. Single-channel openings that might have been responses to non-quantal release of ACh were observed at rates of 0.9-12.3 min-1 (mean 3.0 min-1), only 1-5 times the rate of spontaneous AChR channel openings in uninnervated myocytes (mean 1.4 min-1). 4. We conclude that there is no significant non-quantal ACh leak from the presynaptic contacts in these immature synapses under these culture conditions. This is in disagreement with other, less direct, experimental reports, but consistent with findings in mature frog motor nerve terminals.

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Changes in muscle length cause large changes in the probability of transmitter release from frog motor nerve terminals. A 5% to 10% stretch from rest length can increase EPP amplitude or mEPP frequency by more than 100%. The phenomenon is fully reversible and extremely rapid. Within 7-10 milliseconds of the stretch, the enhancement is complete, and it is maintained essentially constant at the new level for as long as the stretch is sustained. Given these properties, the length modulation of release is unquestionably of functional importance, strongly amplifying the spinal stretch reflex. The stretch-induced enhancement of transmitter release persists at a reduced level in a 0 Ca++, 2 mM Mg++ Ringer. This finding indicates a lack of dependence on Ca++ influx from outside the terminal. Release of Ca++ from intracellular stores close to release sites cannot be ruled out as a contributing factor. Our results, however, suggest a mechanism involving physical connections between the extracellular matrix and the nerve terminal that can alter release probability directly. Morphological evidence for connections that might be responsible can be demonstrated in micrographs of deep-etched freeze fractures through neuromuscular junctions. Hypothesizing that the ECM-nerve terminal connections responsible for the stretch effect involve proteins from the integrin family and knowing that many of the integrin-ECM binding interactions occur at sites on the ECM proteins containing the amino acid sequence RGD, we treated preparations with 0 Ca++, 2 mM Mg++ Ringer to reduce integrin binding and then returned the muscle to normal Ringer containing 0.1-0.2 mM of a six-amino-acid peptide containing the RGD sequence. This peptide strongly suppressed the stretch effect, while a control peptide (RGE) had no effect. A 50 microM Ca++/50 microM Mg++ Ringer had little effect on stretch enhancement but permitted a strong inhibition of enhancement when RGD was present. The identity of the ECM molecule(s), the integrin(s), and the mechanism of enhancement of release are unknown. However, our findings imply that much or all of the length-dependent modulation of release probability is mediated by an RGD-sensitive integrin-ECM interaction that depends more on external Ca++ than on Mg++.

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Previous anatomical studies suggest that androgen regulates synapse elimination in the androgen-sensitive levator ani(LA) muscle of the rat. Androgen treatment beginning on postnatal day 7 (P7) prevents some of the normal loss of multiaxonal innervation in this muscle. The present study used physiological techniques to measure the number and size of LA motor units during the synapse elimination period in muscles from normals, and castrates treated with either testosterone propionate or oil. The number of increments in LA twitch tension as nerve stimulation intensity increased, a measure of the number of motor units, was the same at the end (P28) of synapse elimination as near the beginning (P7) of this process. This result indicates that motoneuronal cell death does not contribute to synapse elimination in the LA. Moreover, androgen during this period did not influence the number of LA motor units. In contrast, between P7 and P28, there was a dramatic decline in the size of LA motor units, as indicated by a decrease in the percentage of twitch or tetanus tension of individual motor units relative to the maximal twitch or tetanus tension of the whole muscle. In addition, androgen treatment of castrated males during this period prevented some of the normal decline in the size of LA motor units. Estimates of the number of inputs per LA muscle fiber derived from the number of LA motor units and their average size indicate that androgen maintains polyneuronal innervation in the LA muscle. This finding supports previous anatomical studies suggesting that androgen can prevent synapse elimination in this muscle. The strength of LA synapses was also examined by measuring the tetanus: twitch ratio of individual motor units and by measuring the safety margin of LA synapses. Both measurements indicated that the average strength of LA synapses increases during synapse elimination. Moreover, androgen appeared to spare synapses from elimination without increasing their strength, since androgen-treated muscles generally had larger motor units but the same mean tetanus:twitch ratio and safety margins as untreated LA muscles except at P28, when synapses in androgen-treated LA muscles had appreciably lower safety margins than normal. These results suggest that androgen regulates synapse elimination through a mechanism(s) independent of synaptic strength.

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1. Endogenous adenosine, which is produced by enzymatic degradation of ATP released from synaptic vesicles, has been shown to be a potent inhibitor of acetylcholine release from motor nerve terminals. It has been proposed that this auto-inhibition mechanism might contribute significantly to tetanic stimulation-induced depression. 2. Levels of facilitation and depression during a 20 Hz stimulus train differ greatly in different terminals, but are strongly and non-linearly correlated with the terminal's release characteristics (the amount of transmitter released per unit terminal length, or 'release efficacy'). There is a weaker, approximately linear, correlation between depression and release efficacy at 2 Hz stimulation. 3. The effects of both endogenous and exogenously applied adenosine are also highly variable for different nerve terminals. We have shown that much of this variability can be attributed to the release efficacy of each terminal in the case of endogenous effects, and to the size of the nerve terminal in the case of exogenously applied adenosine receptor agonists. 4. When nerve terminals are pooled according to their individual release characteristics, endogenous adenosine can be shown to contribute significantly to stimulation-induced depression of release primarily in terminals that release enough transmitter to generate significant levels of adenosine, but do not release so much transmitter that depletion of releasable quanta is severe.

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