Abstract
Increases in cAMP have been shown previously to enhance the strength of the granule cell to Purkinje cell synapse. We have examined the mechanisms underlying this enhancement in rat cerebellar brain slices. Elevation of cAMP levels by forskolin increased synaptic currents in a dose-dependent manner. Fluorometric calcium measurements revealed that forskolin did not affect presynaptic calcium influx or resting calcium levels. The waveform of the presynaptic volley was also unaltered, indicating that changes in the presynaptic action potential did not contribute to synaptic enhancement. However, forskolin enhanced the frequency but not the size of spontaneous miniature EPSCs. There was a one-to-one correspondence between increases of spontaneous and evoked neurotransmitter release. These results suggest that forskolin increases release at this synapse via presynaptic mechanisms that do not alter calcium influx. The effect of forskolin on paired-pulse facilitation was examined to assess the relative contributions of changes in the probability of release (p) and changes in the number of functional release sites (n) to this form of enhancement. These experiments suggest that although small changes in n cannot be excluded, most of the enhancement arises from increases in p.
- synaptic modulation
- cAMP
- magnesium green
- fura-2
- mEPSC
- forskolin
- Purkinje cell
- granule cell
- paired-pulse facilitation
Many neuromodulators can rapidly change the strength of granule cell to Purkinje cell synapses (Sabatini and Regehr, 1995; Dittman and Regehr, 1996; Salin et al., 1996). One such modulator is cAMP. Elevation of cAMP levels leads to a large and rapid presynaptic enhancement, presumably by activating protein kinase A (PKA) (Salin et al., 1996). At present, the mechanisms by which cAMP modulates this synapse are not known.
At other synapses, changes in cAMP levels act via a variety of mechanisms to modify synaptic strength. Spike broadening contributes to cAMP-dependent enhancement of the Aplysia sensorimotor synapses of the abdominal ganglion (Byrne and Kandel, 1996). Presynaptic mechanisms independent of calcium have been implicated in cAMP-dependent modulation in Aplysia, the crayfish neuromuscular junction, both inhibitory and excitatory hippocampal synapses, and inhibitory cerebellar synapses (Goy and Kravitz, 1989;Dale and Kandel, 1990; Delaney et al., 1991; Llano and Gerschenfeld, 1993; Chavez-Noriega and Stevens, 1994; Weisskopf et al., 1994; Capogna et al., 1995; Trudeau et al., 1996; Kondo and Marty, 1997). In the hippocampus, cAMP can also act postsynaptically by modifying ligand-gated receptors (Greengard et al., 1991). In addition, cAMP has been shown to modulate voltage-gated calcium channels (Hille, 1992). Thus, based on the diverse targets of cAMP, many possible mechanisms could be involved in cAMP-mediated enhancement at the granule cell to Purkinje cell synapse.
Understanding the actions of cAMP has important implications for a presynaptic form of long-term potentiation (LTP). It has been shown that presynaptic activity leads to a long-term enhancement of neurotransmitter release at the granule cell to Purkinje cell synapse (Salin et al., 1996). This presynaptic form of LTP involves cAMP and is similar to forms of use-dependent enhancement at the crayfish neuromuscular junction and mossy fiber synapses in the hippocampus (Dixon and Atwood, 1989; Huang et al., 1994; Weisskopf et al., 1994;Salin et al., 1996). At these synapses, changes in the probability of release (p) and in the number of release sites (n) have both been shown to contribute to LTP (Wojtowicz et al., 1988, 1994; Weisskopf et al., 1994; Weisskopf and Nicoll, 1995;Tong et al., 1996). However, at the granule cell to Purkinje cell synapse, the contributions of changes in n and pto cAMP-dependent modulation are not known.
Here we study the mechanisms of cAMP-dependent enhancement of transmission in rat cerebellar slices. Forskolin was used to elevate cAMP levels by activating adenylate cyclase (Zhang et al., 1997). We studied the effects of cAMP on fiber excitability, action potential waveform, presynaptic calcium influx, and vesicular release. We show that changes in presynaptic calcium influx are not involved in cAMP-mediated increases in synaptic strength. Moreover, we find that cAMP acts downstream from calcium influx to increase the probability of vesicular release.
MATERIALS AND METHODS
Electrophysiology. Transverse slices, 300 μm thick, were cut from the cerebellar vermis of 9- to 15-d-old Sprague Dawley rats as described previously (Llano et al., 1991; Dittman and Regehr, 1996). Slices were maintained in a chamber with an external solution containing (in mm): 125 NaCl, 2.5 KCl, 2 CaCl2, 1 MgCl2, 2.6 NaHCO3, 1.25 NaH2PO4, and 25 glucose that was continuously bubbled with 95% O2/5% CO2. The external recording solution was the same with bicuculline added at 20 μm to suppress inhibitory currents. Slices were continuously perfused with bubbled 95% O2/5% CO2 external solution at 1–3 ml/min in the recording chamber.
Synaptic EPSCs. Whole-cell recordings of Purkinje cells were obtained as described previously (Llano et al., 1991; Mintz et al., 1995), using 1.0–1.9 MΩ glass pipettes. The internal solution used in measurements of evoked (EPSC) and spontaneous miniature EPSCs (mEPSCs) contained (in mm): 110 Cs2SO4, 10 EGTA, 4 CaCl2, 1.5 MgCl2, 5.5 MgSO4, 4 Na2-ATP, 0.1 D600, and 10 HEPES, pH 7.4 (CsOH). After a high resistance seal was obtained, suction was applied lightly through the pipette to break through the membrane. The cell was then maintained at −70 mV for several minutes to allow diffusion of the internal solution into the cell body and dendrites. Access resistance (<5 MΩ after series resistance compensation) and leak current were monitored continuously.
Parallel fibers were stimulated extracellularly by injecting a current pulse through a saline-filled glass electrode situated 0.5–1 mm from the recording electrode in the molecular layer. Synaptic currents were recorded at 20 kHz and filtered at 1 kHz. Interstimulus intervals ranged from 15 to 30 sec for experiments measuring evoked EPSCs. Experiments involving paired-pulse facilitation and mEPSCs had an interstimulus interval of 30 sec. Stimulus intensities ranged from 2.5 to 10 μA and were 0.2–0.4 msec in duration. To assess whether changes in fiber stimulus threshold could contribute to the enhancement seen in the presence of forskolin, we performed similar experiments in the presence of 0.5–1 mm kynurenic acid (KYN). In the presence of this low affinity competitive AMPA receptor antagonist, stimulus intensities ranging from 7 to 20 μA were used to evoke EPSCs. The forskolin-mediated enhancement was unchanged with higher stimulus intensities (n = 6). Because there was no change in the forskolin effect in KYN, these experiments were included in the average time courses (see Fig. 1B).
Forskolin enhances synaptic currents in a dose-dependent manner. A, Continuous application of 50 μm forskolin causes a rapid increase in the Purkinje cell EPSC. The time course of the peak current is plotted before and after the addition of forskolin (bar). Theinset shows averaged EPSCs before (thin line) and after (thick line) exposure to the drug. The time constant of decay of the EPSC in forskolin (6.1 msec) was not significantly changed from that of control (5.3 msec).Traces are the averages of 15–20 trials.B, Summary of the mean relative responses (± SEM) of synaptic currents to continuous application of 1 μm(circles; 207 ± 38%; n = 5), 20 μm (squares; 290 ± 42%;n = 10), and 50 μm(triangles; 390 ± 45%; n = 11) forskolin and of 50 μm 1,9-dideoxy-forskolin (diamonds; 115 ± 15%; n = 3). The time course of each experiment is normalized to the average control peak EPSC. Forskolin was added at time 0.
Stock solutions of forskolin and 1,9-dideoxy-forskolin (Research Biochemicals, Natick, MA) were dissolved in dimethylsulfoxide (DMSO) and stored at −80°C at 50–100 mm concentrations. A few minutes before the application of the drug, the stock solution was thawed and diluted directly into the bath reservoir. Control solutions always contained 0.1% DMSO. Kynurenic acid (Research Biochemicals) was solubilized in distilled water and stored at −20°C at 100 mm stock concentrations. Dilution to final concentrations were made just before the start of the experiment. Recordings were performed between 22 and 25°C.
Measurement of mEPSCs. mEPSCs were recorded in the whole-cell configuration using 1.3–1.7 MΩ pipettes filled with the same internal solution used to measure evoked EPSCs. TTX (0.25 μm) and 20 μm bicuculline were included in the standard external solution to block action potential-evoked synaptic currents and IPSCs, respectively. In some experiments 50 μm Cd2+ was also included in the external solution to block voltage-gated calcium channels (Mintz et al., 1995). Cd2+ did not reliably alter the basal mEPSC frequency or the effects of forskolin on mEPSC frequency; 50 μm forskolin increased mEPSC frequency to 260 ± 9% (n = 3) in Cd2+ plus TTX compared with 280 ± 8% (n = 4) in the presence of TTX alone. Cd2+ was not routinely included in our experiments because it adversely affected the stability of recordings. Data were recorded in 20 sec epochs, sampled at 2.5 kHz, and filtered at 500 Hz with an eight-pole Bessel filter (Frequency Devices, Haverhill, MA). Membrane potential was maintained at −70 mV unless otherwise indicated. To minimize the noise, we did not use series resistance compensation. Leak currents were −10 to −100 pA. Events were counted and analyzed off-line using IGOR PRO software (Wavemetrics, Lake Oswego, OR) and custom macros (provided by Bernardo Sabatini). Inclusion criteria were a 4–6 pA amplitude threshold, a minimum rate of rise of 0.4 pA/msec, and a decay time constant between 3 and 12 msec. Amplitude histograms were binned in 2 pA intervals. Cumulative amplitude histograms were compared using the Kolmogorov–Smirnov test for significance. Statistical significance was assumed for P ≤ 0.05.
Extracellular field recordings. Presynaptic volleys and calcium indicator fluorescence were recorded simultaneously. A saline-filled electrode (2–2.5 MΩ) was placed near the surface of the parallel fibers within the 150-μm-diameter spot used to measure fluorescence and 400–700 μm away from the stimulus site. The position of the electrode was chosen to maximize the amplitude of the presynaptic volley and the ΔF/F signal while maintaining separation between the volley and the stimulus artifact. Stimulus strength ranged from 40 to 120 μA.
Calcium-sensitive fluorescence measurements. Parallel fibers were labeled by local application of either magnesium green (Zhao et al., 1996) or fura-2 (Grynkiewicz et al., 1985) as described previously (Regehr and Tank, 1991; Regehr and Atluri, 1995). The fluorescence output was measured with a photodiode, sampled at 10 kHz, and filtered at 500 Hz. The interstimulus interval was 30 sec. The ΔF/F ratio from a single stimulus was calculated and used as a linear measure of presynaptic calcium influx (Mintz et al., 1995; Regehr and Atluri, 1995). Resting calcium levels were monitored with fura-2 using 340 and 380 nm excitation and the ratio method (Grynkiewicz et al., 1985).
RESULTS
Forskolin-mediated modulation of evoked and spontaneous synaptic transmission
Forskolin-mediated changes in synaptic strength were examined at connections between cerebellar granule cells and Purkinje cells. To facilitate voltage control of synaptic responses, we used large electrodes, kept synaptic currents small, and performed experiments on slices from young rats (see Materials and Methods). In all experiments, forskolin was applied continuously to ensure a maximal effect for a given dosage. In Figure1A, the addition of 50 μm forskolin resulted in a rapid and sustained enhancement of the peak EPSC from ∼150 to 650 pA, without significantly affecting its time course. The enhancement produced by 50 μm forskolin was large (390 ± 45% of control;n = 11) and variable (198–615% of control). Figure1B summarizes the dose dependence of the forskolin-induced enhancement of synaptic strength. Synaptic currents began to increase 1–2 min after exposure to forskolin and reached steady state within 7–10 min. In contrast, 50 μm1,9-dideoxy-forskolin, an analog that is ineffective at stimulating adenylate cyclase, did not alter the peak EPSC.
Next we evaluated the effects of forskolin on mEPSCs measured in the presence of TTX. Figure2A shows a typical response of mEPSCs to 50 μm forskolin. Consecutive recordings of mEPSC before (left) and 30 min after (right) application of forskolin are shown. Bottom traces are shown at an expanded time scale to demonstrate that mEPSCs can be easily resolved. mEPSC frequency increased within a few minutes of forskolin application (Fig. 2B). In this example, the mEPSC frequency increases from 7 to 21 Hz.
Forskolin enhances spontaneous mEPSCs.A, Purkinje cell mEPSCs recorded before (left) and after (right) application of 50 μm forskolin. Unprocessed traces shown in compressed time scale are taken from the last 5 sec of four consecutive 20 sec epochs. Below each side is a traceshown in expanded time scale. B, Time course of the average mEPSC frequency in 20 sec epochs during continuous exposure to 50 μm forskolin from time 0. The example is taken from the same experiment shown in A. C, Amplitude histograms from the same experiment for control (thin line) and 50 μm forskolin (bold line) at a holding potential of −70 mV. Insetshows that normalized cumulative amplitude distributions for control (thin line) and forskolin (bold line) are similar (P = 0.85 by Kolmogorov–Smirnov test).
The amplitude histograms of mEPSCs for control (thin line) and 50 μm forskolin (bold line) are shown in Figure 2C. There was a clear increase in the mEPSC frequency at all amplitudes in the presence of forskolin. However, as shown by the normalized cumulative distribution (Fig. 2C, inset), there was no significant change in the mEPSC amplitude distribution. To evaluate our ability to detect changes in mEPSC amplitudes, we depolarized the cell at the end of the experiment from −70 to −50 mV, and a statistically significant change in the mEPSC amplitude profile was detected in the normalized amplitude histogram (P = 0.03 by Kolmogorov–Smirnov test; data not shown). Thus, in this experiment, forskolin increased mEPSC frequency without affecting mEPSC amplitude.
A summary of the mean relative enhancement of mEPSC frequency at different forskolin doses is shown in Figure3. In these experiments, the average baseline mEPSC frequency was between 5 and 8 Hz. For 1, 20, and 50 μm forskolin, spontaneous mEPSC frequency increased within 5 min after exposure to the drug and reached steady state in 20–30 min. At all doses of forskolin, amplitude distributions were not significantly different from that of control. In contrast, addition of 50 μm 1,9-dideoxy-forskolin resulted in only a slight increase in mEPSC frequency.
Forskolin enhances mEPSC in a dose-dependent manner. Summary of the average relative responses of spontaneous mEPSCs to application of 1 μm (circles; 170 ± 5%; n = 4), 20 μm(triangles; 230 ± 6%; n = 6), and 50 μm (squares; 280 ± 8%;n = 4) forskolin as well as 50 μm1,9-dideoxy-forskolin (diamonds; 126 ± 12%;n = 3). Forskolin was applied continuously from time 0. The time course of each experiment was normalized to the average baseline frequency of control mEPSC. No significant change in the mEPSC amplitude distributions was detected at any dose of forskolin (e.g., at 50 μm forskolin, P = 0.88 ± 0.04; n = 4).
Comparing the actions of forskolin on mEPSC frequency and evoked EPSCs reveals two interesting features; the enhancement of mEPSC reaches steady state more slowly and is less variable than that of evoked EPSCs. Both observations reflect the conditions of these different types of experiments. The evoked EPSCs are produced by activation of a few synapses near the surface of the slice. In contrast, the mEPSCs result from many synapses on all regions of the Purkinje cell, which extends deep within the slice. Consequently, the effects of forskolin reach steady state more slowly in the mEPSC experiments as a result of the time taken for this lipophilic agent to diffuse to sites deep within the slice. Furthermore, the lower variability in the effects of forskolin on mEPSCs likely reflects the contributions of larger numbers of synapses in these experiments compared with the evoked EPSC experiments.
The effects of forskolin on presynaptic calcium influx and fiber excitability
Because cAMP has been shown to modulate calcium channels and to affect the presynaptic waveform (Hille, 1992), we tested whether increases in presynaptic calcium entry contributed to synaptic enhancement by forskolin. As described previously, low affinity calcium indicators can be used to detect changes in presynaptic calcium entry at the synapse between granule cells and Purkinje cells (Regehr and Atluri, 1995). We labeled parallel fibers with the calcium-sensitive indicator magnesium green and assessed the effect of forskolin on the stimulus-evoked changes in fluorescence (ΔF/Fsignals). As shown in Figure4A, 20 μmforskolin increased ΔF/F signals by ∼30%. This enhancement could result from either an elevation of presynaptic calcium entry or a change in fiber excitability. To distinguish between these possibilities, we tested the effect of forskolin on fiber excitability by simultaneously measuring the presynaptic volley (Fig.4B). The presynaptic volley, which is the field potential associated with the propagating action potential in the parallel fibers, provides a sensitive means of testing for changes in the number of activated fibers (Sabatini and Regehr, 1995, 1997). Forskolin (20 μm) increased the amplitude of the presynaptic volley by ∼35%, indicating a change in fiber excitability. Forskolin did not significantly affect the waveform of the presynaptic action potential, because the shape of the presynaptic volley was virtually unaltered. However, the latency between stimulus and volley was reduced, suggesting that the conduction velocity was increased (Fig. 4B, inset). As shown in Figure 4C, forskolin enhanced the presynaptic volley and ΔF/F signals with a similar time course and to a comparable degree.
Effects of forskolin on presynaptic calcium transients. A, B, Simultaneous time courses of the amplitude of peak magnesium green fluorescence transients (A) and presynaptic volleys (B) during exposure to 20 μmforskolin (t = 0). Insets show superimposed average traces of control (thin line) and forskolin (bold line) ΔF/F (A) and volleys (B). Each trace is an average of 20 trials. The stimulus artifact, determined by the addition of 1 μm TTX at the end of the experiment, was subtracted off the averaged traces of presynaptic volleys.C, The same time courses shown in A(circles) and B (squares) are normalized to their respective mean control values. Forskolin enhancement of presynaptic volley (35%) is very similar to that of presynaptic calcium transients (30%). D, Plot of the relative magnesium green fluorescence transient as a function of the relative enhancement of presynaptic volley for (from left to right) 1 μm (n = 4), 50 μm (n = 8), and 20 μm(n = 4) forskolin. Thin linerepresents x = y.
A summary of many such experiments revealed that forskolin had a small effect on both fiber excitability and ΔF/Fsignals (Fig. 4D). The dose dependence seemed to differ from that of forskolin-mediated synaptic enhancement, because 20 μm forskolin resulted in maximal elevation of fiber excitability. There was an approximately one-to-one correspondence between the changes in fiber excitability and presynaptic calcium (Fig.4D), suggesting that the small increase in fiber excitability seen in the presence of forskolin accounts for the enhancement seen in ΔF/F signals.
We reexamined the involvement of changes in presynaptic calcium influx using an approach that is unaffected by changes in fiber excitability (Sabatini and Regehr, 1995). This method capitalizes on the fact that after single action potentials, presynaptic calcium levels are sufficiently large to begin to saturate high affinity calcium indicators, such as fura-2. The degree of saturation is determined by the ratio of the fluorescence changes produced by one and two stimuli [(ΔF/F)2/(ΔF/F)1]. This ratio provides a means of quantitating changes in calcium influx that is insensitive to alterations in fiber excitability. An increase in influx decreases (ΔF/F)2/(ΔF/F)1. Superimposed average traces of the ΔF/F transients for one and two stimuli are shown for control conditions in Figure5A (left). Forskolin increased the amplitude of both ΔF/Fsignals (Fig. 5A, middle), but the relative size of the two signals was unchanged. This is apparent in Figure5A (right) in which the traces in control conditions and in forskolin were normalized to the transients produced by single stimuli. Figure 5B shows the time course of the effect of 50 μm forskolin on the fura-2 ΔF/F changes for one and two stimuli (top). The ratio of ΔF/F signals produced by one and two stimuli are plotted below on the same time scale. The results of four experiments are summarized in Figure 5C. Presynaptic calcium influx, which is directly determined by the ratio (ΔF/F)2/(ΔF/F)1, is unaffected by the addition of forskolin. Thus the results of two independent methods show that forskolin does not increase presynaptic calcium influx.
Fura-2 fluorescence measurements of presynaptic calcium influx. A, Average traces of fluorescence changes produced by one stimulus superimposed on that of two stimuli in control conditions (left) and in the presence of 50 μm forskolin (middle).Right, The trace for the first stimulus of control is scaled to that of forskolin to emphasize that the relative fluorescence change between one and two stimuli is the same for the two conditions. Traces are the averages of 15–20 trials. B, The time course of peak fura-2 ΔF/F for one (lower curve) and two (upper curve) stimuli before and after the addition of forskolin (time 0). The relative change in ΔF/F for two versus one stimuli is plotted below. C, Summary of the fura-2 fluorescence changes for four experiments. The effects of forskolin on the relative mean ΔF/F values for one (lower curve) and two (upper curve) stimuli are plotted as a function of time. The average ratio of ΔF/F for two versus one stimuli, a direct measurement of the change in calcium influx, is plottedbelow.
In addition, resting calcium levels were monitored using fura-2 and the ratio method (n = 4; data not shown). There was no detectable change in resting ratio, indicating that resting calcium levels were unaltered.
Relationship between evoked and spontaneous EPSCs
The frequency of spontaneous EPSCs can provide a sensitive means of detecting changes in release that are independent of calcium entry. To examine the contribution of calcium-independent changes to the enhancement of evoked release, we compared the effect of forskolin on evoked currents to its effect on mEPSC frequency. To correct for increases in fiber excitability, we divided evoked currents by the average enhancement of ΔF/F (magnesium green) for each forskolin dose. As shown in Figure6, there is a one-to-one correlation between mEPSC frequency and evoked EPSCs at each forskolin dose (fromleft to right, 0, 1, 20, and 50 μm forskolin). This suggests that presynaptic effects independent of calcium influx account for all of the forskolin-mediated enhancement of the granule cell to Purkinje cell synapse (see Discussion).
Relationship of forskolin enhancement of evoked to spontaneous release. Plot of the average relative peak EPSC of evoked versus spontaneous responses for (left to right) 0 (theoretical point), 1, 20, and 50 μm forskolin. The relative peak EPSCs were corrected for small enhancements of presynaptic volley by dividing the mean relative evoked enhancement (see Fig. 1B) by the mean relative ΔF/F enhancement (see Fig.4D) for each forskolin concentration. Thin line represents x = y.
The effect of forskolin on paired-pulse facilitation
Paired-pulse facilitation (ppf), the short-term enhancement of release that persists for tens of milliseconds after a single conditioning pulse, can be used to detect changes in the probability of release (Zucker, 1973, 1989; Manabe et al., 1993; Atluri and Regehr, 1996). At the granule cell to Purkinje cell synapse, it has been shown previously that in conjunction with an enhancement of synaptic strength, a brief application of forskolin decreases ppf (Salin et al., 1996). We examined the effects of forskolin on ppf to determine whether a change in the probability of release (p) was sufficient to account for all of the synaptic enhancement.
We first quantified the effect of a sustained application of forskolin on ppf in 2 mm external calcium (Cae). In these experiments, the second synaptic current in forskolin can be more than eightfold larger than the first current in control conditions. This makes accurate quantification of the effect of forskolin on ppf difficult, because large synaptic currents can lead to series resistance errors and an underestimation of ppf, and small synaptic currents are highly variable. One strategy would be to reduce the stimulus strength in the presence of forskolin to minimize the effects of series resistance. However, because different fibers exhibited different degrees of ppf, we believed it was necessary to maintain the same stimulus intensity. We therefore had stringent criteria for the rejection of experiments in which series resistance errors would affect the results. We found that the most sensitive measure of changes in series resistance was the time constant of the decay of the synaptic currents. Experiments were rejected if the time constant of decay of two EPSCs in a pair of pulses differed by >10%. Figure 7A shows an example of an experiment in which the peak EPSC evoked by each of two stimuli separated by 30 msec was monitored before and after exposure to 50 μm forskolin. The facilitation ratio peak2/peak1, which is plotted below on the same time scale, decreased in the presence of forskolin. This decrease in ppf is also apparent when the average EPSCs measured in control conditions and in the presence of forskolin are normalized and superimposed (Fig. 7A, bottom right panel).
Effects of forskolin on paired-pulse facilitation.A, Peak EPSCs of two stimuli separated by 30 msec were plotted as a function of time before and after 50 μmforskolin application (time 0). The amount of facilitation, recorded as the ratio of the amplitude of the second peak (white) to that of the first peak (black) is shownbelow. The top right panel shows the average traces for control (thin line) and 50 μm forskolin (bold line) currents. Scaling of the first peak of the control trace to the first peak of the forskolin trace shows a decrease of facilitation in the presence of forskolin (bottom right panel). Traces are averages of 10–15 trials. Stimulus artifacts are blanked for clarity. B, Analogous experiment to that described in A except 750 μm kynurenic acid is present. C, Mean ± SEM of the relative facilitation before and after the continuous application of 50 μm forskolin (circles;n = 4) or 1,9-dideoxy-forskolin (squares; n = 4). Drug application occurred at time 0. The time course of the facilitated ratio of each experiment was normalized to its mean control value. Eachpoint in the time course of the facilitation ratio represents the average value of three consecutive time points.
We also examined the effects of forskolin on ppf in the presence of KYN (750 μm). This allowed us to minimize the synaptic variability and, as shown in Figure 7B, to perform experiments with smaller baseline synaptic currents. Neither the degree of facilitation nor the enhancement by 50 μm forskolin were altered by KYN. When normalized to the first synaptic current, superposition of the average EPSC in control conditions and in the presence of forskolin shows a clear decrease in ppf in the presence of forskolin (Fig. 7B, bottom right panel). A summary of the response of the facilitation ratio to application of 50 μm forskolin is shown in Figure 7C (circles). 1,9-Dideoxy-forskolin did not affect ppf (Fig. 7C, squares).
These experiments confirm the finding that forskolin reduces the magnitude of paired-pulse facilitation, indicating that the averagep increased. Forskolin (50 μm) enhanced evoked EPSCs by 320 ± 50% (when corrected for fiber excitability) and decreased ppf by 29 ± 4% (n = 4). In comparison, increasing Cae from 1 to 2 mm, which increases evoked EPSCs to 330% by increasing p, decreases the facilitation ratio by 37% (P. P. Atluri and W. G. Regehr, unpublished observations). The similarity in the effect on facilitation for these two manipulations that result in the same degree of enhancement suggests that forskolin acts mainly by increasingP.
DISCUSSION
Calcium-independent presynaptic modulation
Various approaches were taken to determine the site(s) of action of cAMP in enhancing transmission at the granule cell to Purkinje cell synapse. Based on these experiments, several possible sites of action were ruled out. Resting Cai levels were unchanged. In addition, mEPSC size remained constant, indicating that postsynaptic receptor sensitivity was unaltered. Perhaps most surprisingly, several lines of evidence indicate that changes in presynaptic calcium entry do not contribute to the synaptic enhancement produced by forskolin. There was no significant change in the shape of the presynaptic volley, which is a sensitive means of detecting changes in the presynaptic waveform; this indicates that indirect effects on calcium channel activation resulting from spike broadening do not contribute to cAMP-mediated enhancement at this synapse. We also examined the possibility that calcium channel activity was modulated. Although there were small increases in the amplitude of presynaptic ΔF/Fsignals for calcium-sensitive indicators, these were a consequence of increases in fiber excitability. Furthermore, an assay that was insensitive to changes in fiber excitability revealed no significant change in calcium influx (an increase of 2.3 ± 3.7%).
Together these experiments established that for our experimental conditions, spike broadening, presynaptic calcium channel modulation, changes in resting calcium levels, and changes in postsynaptic neurotransmitter sensitivity do not contribute to cAMP-dependent plasticity at this synapse. This establishes that forskolin affected synaptic strength exclusively by presynaptic changes downstream from calcium influx. Similar forms of synaptic modulation have been widely reported (Man-Son-Hing et al., 1989; Dale and Kandel, 1990; Delaney et al., 1991; Scanziani et al., 1992); however the molecular sites of action have not been identified. Such synaptic modifications are generally correlated with changes in mEPSC frequency, and this held for forskolin at the granule cell to Purkinje cell synapse.
Although the correlation between altered mEPSC frequency and changes in the amplitude of evoked EPSC supports a contribution from calcium-independent mechanisms to the modulation of many synapses, it has often been difficult to rule out involvement of additional mechanisms. Indeed, in many cases, multiple mechanisms can work together to modify synaptic strength. For example, at this synapse, activation of GABAB-mediated inhibition is a consequence of decreased presynaptic calcium entry and calcium-independent mechanisms (Dittman and Regehr, 1996). We have shown that the modulation of the granule cell to Purkinje cell synapse by forskolin occurs solely via presynaptic processes downstream from calcium entry. This study is one of the few examples in which contributions from other mechanisms could be excluded (Delaney et al., 1991; Trudeau et al., 1996).
What is the relationship between mEPSC frequency and the amplitude of evoked EPSCs? Although detection of changes in mEPSC frequency has been a valuable tool in the study of synaptic transmission, the factors governing mEPSC frequency are not fully understood. In many instances, mEPSC frequency and evoked EPSC amplitude are linked, but this is not always the case (Littleton et al., 1993; Broadie et al., 1994;Diantonio and Schwarz, 1994). Only rarely has the relationship between mEPSC frequency and the amplitude of evoked EPSCs been quantitatively examined (Shapira et al., 1987; Abdul-Ghani et al., 1991; Van der Kloot and Molgo, 1994). Here we are able to compare changes in evoked amplitudes and mEPSC frequency produced by forskolin. For these conditions, there is a one-to-one correspondence between the amplitude of evoked EPSCs and mEPSC frequency.
The effect of cAMP on the probability of release and the number of release sites
Neurotransmitter release depends on the mean probability of release p and on the number of functional release sitesn. Altering either the number of competent presynaptic or postsynaptic sites will change n, as it is defined here. Because paired-pulse facilitation depends on the initial probability of release, it provides a means of distinguishing between changes inp and n. An increase in p will decrease ppf, whereas an increase in n does not affect ppf. The decrease in ppf observed in 2 mm Caeindicates that an increase in p contributes to the synaptic enhancement produced by forskolin, consistent with previous reports at this synapse (Salin et al., 1996). Furthermore, the similarities between the effects of forskolin and changing Cae on ppf also suggest that forskolin acts primarily by increasingp.
cAMP has been shown to modulate other synapses by increasing bothp and n. At the crayfish neuromuscular junction and dentate granule cell synapses, tetanic stimulation produces sustained enhancement of synaptic strength that is mediated by cAMP and PKA. In crayfish, increases in p account for ∼80% of this enhancement, whereas an increase in the mean number of active release sites (presumably corresponding to n) accounts for the rest (Wojtowicz et al., 1988). cAMP also regulates release from dentate granule cells in the hippocampus by changing both n andp (Weisskopf et al., 1994; Tong et al., 1996). In our experiments, it seems that enhancement is primarily a consequence of increases in p, although it is not possible to rule out a small contribution from changes in n as well.
In summary, cAMP acts presynaptically, at a site downstream from calcium entry, to enhance transmission at the granule cell to Purkinje cell synapse. Most of this enhancement is a result of increases inp.
Footnotes
This work was supported by National Institutes of Health Grant R01-NS32405-01 and a grant from the Edward R. and Anne G. Lefler Center to W.R. and by the Howard Hughes Physician Postdoctoral Fellowship to C.C. We thank Pradeep Atluri, Bernardo Sabatini, Jeremy Dittman, and Bruce Peters for comments on this manuscript.
Correspondence should be addressed to Dr. Wade Regehr, Department of Neurobiology, Harvard Medical School, 220 Longwood Avenue, Boston MA 02115.
REFERENCES
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