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REPORT
Department of Molecular and Cell Biology and Helen Wills Neuroscience Institute, University of California, Berkeley, California 94720
Submitted 4 February 2004; accepted in final form 3 March 2004
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ABSTRACT |
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 TOP ABSTRACT INTRODUCTIONMETHODSRESULTSDISCUSSIONGRANTSDISCLOSURESACKNOWLEDGMENTSREFERENCES |
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INTRODUCTION |
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TOPABSTRACTINTRODUCTIONMETHODSRESULTSDISCUSSIONGRANTSDISCLOSURESACKNOWLEDGMENTSREFERENCES |
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). In crayfish, this is caused, at least in part, by an increase in circulating levels of serotonin, which acts to enhance transmitter release to motor neuron action potentials at glutamatergic neuromuscular junctions onto tonic limb muscles (Glusman and Kravitz 1982). Recent studies of the mechanism of serotonin action reveal that at least part of its action is mediated by an elevation of presynaptic levels of cAMP, which in turn operates on two protein targets: hyperpolarization and cyclic nucleotide-activated (HCN) channels (Beaumont and Zucker 2000) and exchange protein activated by cAMP (Epac) (N. Zhong and R. S. Zucker, unpublished observations). Activation of both targets is required for full enhancement of transmission, but it is not yet clear how the activation of either of these targets enhances transmitter release.
Previous work (Delaney et al. 1991) showed that serotonin could cause a modest elevation of presynaptic [Ca2+]i level, although the measured rises were somewhat haphazard and confined to preterminal regions of the motor neuron endings. Very rarely was serotonin seen to elevate [Ca2+]i in presynaptic boutons, but in some axonal branches, [Ca2+]i rose by 30–120 nM from a typical resting level of 165 nM. Presynaptic EGTA injection sufficient to reduce the build-up of [Ca2+]i during repetitive stimulation had no effect on serotonin enhancement of transmission, but the effects on the modest and sporadic [Ca2+]i rises in serotonin were not monitored.
A recent report (Yu et al. 2004) indicates that cloned human HCN4 channels admit a very small amount of Ca2+, about 0.6% of the net inward current, when expressed in HEK293 cells, and that under certain conditions, this Ca2+ entry can enhance transmitter release to subsequent action potentials. This suggested the possibility that the small and sporadic rises in [Ca2+]i accompanying exposure to serotonin might reflect a Ca2+ influx through presynaptic HCN channels and that Ca2+ might act locally near channel mouths, perhaps at undetectable levels in presynaptic boutons, to sensitize synaptic transmission. We have therefore collected some previously obtained but unpublished results and performed some additional experiments to test this possibility more directly.
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METHODS |
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TOPABSTRACTINTRODUCTIONMETHODSRESULTSDISCUSSIONGRANTSDISCLOSURESACKNOWLEDGMENTSREFERENCES |
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; Zhong et al. 2001). The opener muscle was exposed, and the exciter motor neuron was stimulated with a suction electrode in the leg nerve in the meropodite. Preparations were bathed in 
1 ml of a medium containing (in mM) 195 NaCl, 13.5 CaCl2, 5.4 KCl, 2.6 MgCl2, and 10 Na-HEPES (pH 7.4) at 15–17°C. Drugs were applied by switching the perfusion solution (1–2 ml/min) to one containing the drug or drugs shown. Drugs used included serotonin (Sigma Chemical, St. Louis, MO), forskolin (ED Biosciences, Pasadena, CA), ZD 7288 (Tocris Cookson, Ballwin, MO), 
-agatoxin IVA (Calbiochem, La Jolla, CA), and BAPTA-AM (Molecular Probes, Eugene, OR). Nerves were loaded with BAPTA by incubating for 30 min in 50 µM BAPTA-AM and washing for 30 min in normal solution to permit full hydrolysis of BAPTA-AM. Forskolin and BAPTA-AM were prepared as stock solutions in DMSO and dissolved before use in a final solution containing 0.1% or less DMSO. Control experiments showed that synaptic transmission was unaffected by this concentration of DMSO. Excitatory junctional potentials (EJPs) were recorded from proximal muscle fibers using sharp microelectrodes (15–25 M
) filled with 3 M KCl. The motor nerve was stimulated at 2 Hz; intracellular signals were filtered at 2 kHz and digitized at 5 kHz for storage on a personal computer using pClamp7 (Axon Instruments, Union City, CA).
Presynaptic [Ca2+]i was measured using the Ca2+-sensitive ratiometric fluorescent dye fura-2 (Teflabs, Austin, TX). Fura-2 was iontophoresed from a microelectrode (containing 17 mM in 200 mM KCl) that penetrated the primary or a secondary motor nerve branch within 200 µm of the preterminal branches and boutons that were imaged. Injecting –10 nA current for 10–15 min produced a final fura-2 concentration in imaged processes of about 150 nM, estimated as described previously (Mulkey and Zucker 1992). The apparatus used for processing fluorescence images obtained using an intensified CCD camera (Quantex, Sunnyvale, CA), and procedures and calibrations used for [Ca2+]i determination were as described before (Zhong et al. 2001). Electrophysiological and [Ca2+]i measurements are presented as mean ± SE, and two-tailed Student's t-tests were used to assess statistical significance.
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RESULTS |
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TOPABSTRACTINTRODUCTIONMETHODSRESULTSDISCUSSIONGRANTSDISCLOSURESACKNOWLEDGMENTSREFERENCES |
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). First, we confirmed that detectable [Ca2+]i elevations are confined to preterminal axonal branches, as reported previously (Delaney et al. 1991). In 16 of 19 experiments, we observed modest [Ca2+]i elevations (41 ± 10 nM) in scattered presynaptic axonal regions. [Ca2+]i usually rose to a plateau level in 5–10 min; examples of effects of serotonin are shown in Fig. 1. In the other three preparations, we detected no changes (<10 nM) in presynaptic [Ca2+]i. We never observed a change in [Ca2+]i from the resting level in presynaptic boutons. Resting [Ca2+]i level ranged between 50 and 170 nM in these experiments.
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), we checked for effects of the adenylyl cyclase activator forskolin (30 µM) on presynaptic [Ca2+]i. In six experiments, forskolin increased [Ca2+]i by 38 ± 19 nM, which was very similar to the average effect of serotonin (41 µM). As with serotonin, [Ca2+]i elevations were only observed in preterminal axonal branches of 5–15 µm diam. In two additional control experiments, we saw no effects of serotonin on [Ca2+]i when the external Ca2+ was removed and substituted with 0.5 mM EGTA. Thus the rise in preterminal [Ca2+]i appears to be due to an influx from outside through channels opened by cAMP elevated by forskolin or serotonin.
To test whether Ca2+ entered through HCN channels, we used the HCN channel inhibitor ZD 7288 to block channel openings by cAMP. We used ZD 7288 at 30 µM, or six times its half-maximal concentration for blocking HCN channels in crayfish (Beaumont and Zucker 2000), a dose that should produce an 83% block of HCN channels (assuming a single and totally effective binding site). In three experiments, 30 µM ZD 7288 reduced the effect of serotonin from 59 ± 18 nM (without the inhibitor) to 12 ± 2 nM (P = 0.05, 2-tailed paired Student's t-test), which is an 80% reduction. Figure 1A shows results of one such experiment. Similarly, in three experiments, 1 mM Cs+ reduced the serotonin-induced increase from 42 ± 15 to 11 ± 12 nM without Cs+ (P < 0.05); a typical result is shown in Fig. 1B. At four times the half-maximal dose in blocking HCN channels (Beaumont and Zucker 2000), 1 mM Cs+ should produce an 80% block, which may be compared with the observed 74% reduction in [Ca2+]i elevation. Control experiments confirm that when preparations are successively exposed to serotonin or forskolin with a wash in between, both exposures increase [Ca2+]i (see Fig. 2B).
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; Wright et al. 1996). We tested for influx through these channels by measuring the [Ca2+]i rise induced by 300 nM serotonin in the presence of 300 nM -agatoxin IVA. In four experiments, the [Ca2+]i rise in preterminal axons was 32 ± 21 nM, which was not significantly different from the effect of serotonin without a P-channel blocker. Similarly, 30 µM forskolin elevated preterminal [Ca2+]i by 30 ± 15 nM in the presence of 300 nM -agatoxin IVA, which was not significantly different from the effect of forskolin without the P-channel blocker. We confirmed that 300 nM -agatoxin IVA completely blocks postsynaptic responses to motor nerve stimulation, as well as the typical rise in [Ca2+]i transients observed with no blocker present (Delaney et al. 1991). Thus it appears that the preterminal [Ca2+]i rise induced by cAMP is mainly, and probably entirely, due to influx through HCN channels.
Even though the preterminal [Ca2+]i rise is quite modest and is only detectable in a presynaptic compartment distinct and distant from presynaptic boutons where transmitter is secreted, it seemed possible that a tiny, unmeasurable Ca2+ influx through HCN channels at presynaptic boutons could mediate the HCN channel–dependent action of cAMP on synaptic transmission. Although presynaptic EGTA injection had been found to be without effect on serotonin's enhancement of transmission, EGTA binds Ca2+ quite slowly, only within about 10 ms at 200 nM [Ca2+]i, and so might not be able to capture Ca2+ ions acting very close to their point of entry before they bind to an effector target. To test this possibility, we loaded nerve terminals with the Ca2+ chelator BAPTA, which binds Ca2+ ions about 100 times faster than EGTA (Neher 1986), and compared effects of 30 µM forskolin on transmission and presynaptic [Ca2+]i levels before and after BAPTA loading.
In eight experiments, after loading nerve terminals with BAPTA, baseline synaptic transmission was reduced (by 42 ± 9%). Synaptic facilitation to a brief train of action potentials was also substantially diminished (by 59 ± 13%, see Fig. 2A). This result is expected, since the addition of exogenous Ca2+ buffer capacity should slow the accumulation of residual Ca2+ responsible for facilitation (Zucker and Regehr 2002). Treating a presynaptic bouton as a single well mixed compartment, residual calcium Ca(t) depends on the Ca2+ influx rate I(t), pump rate at the surface P, and the Ca2+ buffer ratio 
, and is described by the equation
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Pmax/Kp if Ca << Kp, with Pma and Kp the maximum pump rate and its Ca2+ affinity, respectively, and the buffer ratio (the ratio of bound plus free [Ca2+]i to free [Ca2+]i) depends on total concentrations of each of i buffers (Btot,i) and their Ca2+-dissociation constants (KD,i)
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and prolongs the time constant of [Ca2+]i equilibration [
= V/PA for small Ca(t)] and retards the accumulation of facilitation. Similarly, BAPTA loading should retard the rise in [Ca2+]i due to an influx of Ca2+ [I(t)] induced by serotonin or forskolin, and this effect was also observed (Fig. 2B). The steady-state level of [Ca2+]i equals I/P and is unaffected by BAPTA because it is independent of .
The interesting result is the effect of BAPTA loading on the enhancement of transmission by forskolin. There was no significant change in either the amplitude or the time course of the cAMP-dependent enhancement of transmitter release. Without BAPTA loading, the rise in [Ca2+]i in preterminal axons reached a peak of about 40 nM at 25 min after forskolin addition, with a half-rise time of 5.8 ± 0.68 min. This is somewhat before the enhancement of transmission reached its peak (at 35 min), with a half-rise time of 11.1 ± 0.54 min. After BAPTA loading, the peak rise in [Ca2+]i (to 30 nM) was delayed until 35 min, with the half-rise time now occurring at 13.6 ± 0.90 min, while the enhancement of release was not delayed at all, with its half-rise time still at 11.1 ± 0.65 min. Thus without BAPTA, the half-rise time of the [Ca2+]i elevation to forskolin preceded the half-rise time of the effect on transmission, while after BAPTA loading the half-rise time of the [Ca2+]i elevation often followed the half-rise time of the effect on transmission. The differential effects of BAPTA on the time courses of [Ca2+]i change and enhancement of transmission are difficult to reconcile with the rise in [Ca2+]i serving as a direct mediator of the enhanced transmission.
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DISCUSSION |
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TOPABSTRACTINTRODUCTIONMETHODSRESULTSDISCUSSIONGRANTSDISCLOSURESACKNOWLEDGMENTSREFERENCES |
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). It is difficult to imagine how this [Ca2+]i rise, which is too small and in the wrong place, can directly enhance synaptic transmission. This confirms previous observations (Delaney et al. 1991). 2) Most, if not all, of the [Ca2+]i elevation is due to entry of [Ca2+]i through HCN channels opened by cAMP. Little, if any, enters through the presynaptic P-type voltage-dependent Ca2+ channels that admit the Ca2+ responsible for triggering transmitter release to action potentials. This confirms more directly the previous inference (Delaney et al. 1991; Dixon and Atwood 1985; Wojtowicz and Atwood 1984) that the small (4–10 mV) depolarization of presynaptic terminals caused by the cAMP activation of HCN channels (Beaumont and Zucker 2000) cannot enhance transmission by admitting Ca2+ through voltage-dependent channels. Since the cAMP-dependent [Ca2+]i elevation requires external Ca2+, it does not arise from Ca2+ released from internal stores independent of Ca2+ entry. 3) Increasing the cytoplasmic Ca2+ buffering power reduces evoked transmission, slows the growth of synaptic facilitation, and slows the rise in preterminal [Ca2+]i so that it follows slightly, instead of precedes slightly, the cAMP-dependent enhancement in synaptic transmission. It is difficult to imagine how this [Ca2+]i rise can be responsible for enhancing release, which under these circumstances precedes it (as measured by the time to reach half-maximum). 4) Presynaptic BAPTA had no effect at all on the cAMP-dependent enhancement of transmission. If this enhancement were due to the local action of occult, undetectable Ca2+ influx into nerve terminals, BAPTA should have captured these Ca2+ ions before they could act, and blunted the enhancement of transmission. Our results would appear to exclude this possibility.
In conclusion, the enhancement of transmitter release is mediated by activation of HCN channels and Epac (Beaumont and Zucker 2000; N. Zhong, and R. S. Zucker, unpublished observations), operating on the transmitter release machinery, or perhaps the supply of vesicles available for release (Wang and Zucker 1998), apparently without any direct involvement of Ca2+ ions in the process of enhancement.
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GRANTS |
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TOPABSTRACTINTRODUCTIONMETHODSRESULTSDISCUSSIONGRANTSDISCLOSURESACKNOWLEDGMENTSREFERENCES |
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DISCLOSURES |
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TOPABSTRACTINTRODUCTIONMETHODSRESULTSDISCUSSIONGRANTSDISCLOSURESACKNOWLEDGMENTSREFERENCES |
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ACKNOWLEDGMENTS |
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TOPABSTRACTINTRODUCTIONMETHODSRESULTSDISCUSSIONGRANTSDISCLOSURESACKNOWLEDGMENTSREFERENCES |
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FOOTNOTES |
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Address for reprint requests and other correspondence: R. S. Zucker, Dept. of Molecular and Cell Biology, Univ. of California, 111 Life Sciences Addition, Berkeley, CA 94720-3200 (E-mail: zucker{at}socrates.berkeley.edu).
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REFERENCES |
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TOPABSTRACTINTRODUCTIONMETHODSRESULTSDISCUSSIONGRANTSDISCLOSURESACKNOWLEDGMENTSREFERENCES |
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Asterita MF. The Physiology of Stress. New York: Human Sciences, 1985.
Beaumont V and Zucker RS. Enhancement of synaptic transmission by cyclic AMP modulation of presynaptic Ih channels. Nat Neurosci 3: 133–141, 2000.[CrossRef][ISI][Medline]
Cooper RL, Marin L, and Atwood HL. Synaptic differentiation of a single motor neuron: conjoint definition of transmitter release, presynaptic calcium signals, and ultrastructure. J Neurosci 15: 4209–4222, 1995.[Abstract]
Delaney K, Tank DW, and Zucker RS. Presynaptic calcium and serotonin-mediated enhancement of transmitter release at crayfish neuromuscular junction. J Neurosci 11: 2631–2643, 1991.[Abstract]
Dixon D and Atwood HL. Crayfish motor nerve terminal's response to serotonin examined by intracellular microelectrode. J Neurobiol 16: 409–424, 1985.[CrossRef][ISI][Medline]
Glusman S and Kravitz EA. The action of serotonin on excitatory nerve terminals in lobster nerve-muscle preparations. J Physiol 325: 223–241, 1982.
Mulkey RM and Zucker RS. Posttetanic potentiation at the crayfish neuromuscular junction is dependent on both intracellular calcium and sodium ion accumulation. J Neurosci 12: 4327–4336, 1992.[Abstract]
Neher E. Concentration profiles of intracellular calcium in the presence of a diffusible chelator. In: Calcium Electrogenesis and Neuronal Functioning, edited by Heinemann U, Klee M, Neher E, and Singer W. Berlin: Springer, 1986, p. 80–96.
Wang C and Zucker RS. Regulation of synaptic vesicle recycling by calcium and serotonin. Neuron 21: 155–167, 1998.[CrossRef][ISI][Medline]
Wojtowicz JM and Atwood HL. Presynaptic membrane potential and transmitter release at the crayfish neuromuscular junction. J Neurophysiol 52: 99–113, 1984.
Wright SN, Brodwick MS, and Bittner GD. Presynaptic calcium currents at voltage-clamped excitor and inhibitor nerve terminals of crayfish. J Physiol 496: 347–361, 1996.[ISI][Medline]
Yu X, Duan KL, Shang CF, Yu HG, and Zhou Z. Calcium influx through hyperpolarization-activated cation channels (Ih channels) contributes to activity-evoked neuronal secretion. Proc Natl Acad Sci USA 101: 1051–1056, 2004.
Zhong N, Beaumont V, and Zucker RS. Roles for mitochondrial and reverse mode Na+/Ca2+ exchange and the plasmalemma Ca2+ ATPase in post-tetanic potentiation at crayfish neuromuscular junctions. J Neurosci 21: 9598–9607, 2001.
Zucker RS and Regehr WG. Short-term synaptic plasticity. Annu Rev Physiol 64: 355–405, 2002.[CrossRef][ISI][Medline]
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