Spine Ca²⁺ Signaling in Spike-Timing-Dependent Plasticity

Burst-timing-dependent potentiation and depression in L2/3 pyramids

Whole-cell in vivo recordings from morphologically identified barrel-related L2/3 pyramidal neurons indicate large compound EPSPs in response to tactile stimuli but sparse AP responses (Zhu and Connors, 1999; Brecht et al., 2003), with rare burst activity (Svoboda et al., 1997, 1999). The induction of long-lasting changes in synaptic efficacy has been reported to depend strongly on the timing between presynaptic and postsynaptic APs (Markram et al., 1997; Bi and Poo, 1998). Therefore, we first investigated in L2/3 pyramidal neurons whether such a timing dependence also existed for pairing a single compound EPSP that was elicited by focal extracellular stimulation with a burst of three APs occurring at 50 Hz in the postsynaptic cell. We found that the degree of both potentiation and depression depended on the time interval Δt′ between onset of the AP burst and onset of the EPSP (Figs. 1, 2). When the AP burst preceded the EPSP by Δt′ = −90 ms or followed the EPSP by Δt′ = +50 ms, the pairing had no effect (Δt′ = −90 ms: 1.00 ± 0.09, p > 0.5, n = 6; Δt′ = +50 ms: 0.92 ± 0.11, p > 0.5, n = 4). Pairing at Δt′ = −50 ms resulted in a long-lasting depression of the EPSP amplitude, with a reduction of the EPSP amplitude by a factor of 0.68 ± 0.05 (p < 0.01; n = 10) as compared with control (Figs. 1C, 2B). Two APs before and one AP after the EPSP (Δt′ = −30 ms) did not change the EPSP amplitude (0.98 ± 0.12; p > 0.5; n = 8). In contrast, one AP before and two APs after the EPSP (Δt′ = −10 ms) resulted in moderate potentiation (1.42 ± 0.19; p < 0.05; n = 12). Strong potentiation by a factor of 2.01 ± 0.22 (p < 0.01; n = 11) was found if the three APs followed the EPSP by Δt′ = +10 ms (Figs. 1B, 2).

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Figure 1.

Timing-dependent induction of LTP and LTD by pairing an EPSP and a short burst of APs. A, Illustration of the recording configuration for the synaptic plasticity experiments. The extracellular stimulation pipette was placed close to the basal dendrites, ∼50 μm from the soma of the L2/3 pyramidal neuron. B, The induction protocol for LTP is depicted on the left. An EPSP evoked by extracellular stimulation (pre) was paired with a short burst of three APs at 50 Hz elicited by current injections into the postsynaptic cell (post). The first AP followed the onset of the EPSP by Δt = 10 ms. The time interval Δt is defined as the time between the EPSP and the AP closest in time to the EPSP. For bursts that follow the EPSP, Δt is equivalent to Δt′, which is defined as the time interval between the EPSP and the first AP in the burst. Pairing was repeated 60 times, every 10 s. To the right, the EPSP amplitude, membrane potential, and input resistance are plotted over time during the experiment. The dashed line indicates the average EPSP amplitude before the pairing. The pairing protocol depicted to the left resulted in potentiation of the EPSP amplitude. The EPSPs averaged over the times indicated by the red bars are shown on the bottom. The average EPSP amplitude increased from 2 to 3.5 mV at 20–40 min after the pairing period. C, The protocol for the induction of LTD is depicted to the left. A short burst of three APs at 50 Hz was paired with a following EPSP. Here the first AP in the burst preceded the onset of the EPSP by Δt′ = −50 ms, which is equivalent to the definition that the last AP in the burst preceded the onset of the EPSP by Δt = −10 ms. To the right, the EPSP amplitude, membrane potential, and input resistance are plotted over time for the experiment in which the burst preceded the EPSP. This pairing protocol resulted in depression of the EPSP amplitude. The voltage recordings averaged over the times indicated by the red bars are shown on the bottom. The average EPSP amplitude decreased from 2 to 1 mV at 20–40 min after the pairing period.

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Figure 2.

Burst-timing-dependent plasticity curve. A, Pooled and normalized EPSP amplitudes for different time intervals Δt′ between the onset of the EPSP and the first AP in the burst. The burst consisted of three APs (50 Hz). Insets show schematically the timing between the EPSP and the three APs. B, Summary of the change in the EPSP amplitude for different EPSP and AP burst-timing intervals Δt′. If the AP burst preceded the EPSP by more than −90 ms or followed by more than +50 ms, no change in EPSP amplitude was found (p > 0.5; n = 4–6). A timing interval of Δt′ = −50 ms resulted in depression of the EPSP amplitude by a factor of 0.67 ± 0.06 (mean ± SEM; **p < 0.01; n = 9), whereas a timing interval of Δt′ = +10 ms resulted in potentiation by a factor of 2.08 ± 0.25 (**p < 0.01; n = 11). If the EPSP was evoked within the AP burst, either no change (Δt′ = −30 ms; p > 0.5; n = 8) or potentiation by a factor of 1.5 ± 0.3 (Δt′ = −10 ms; *p < 0.05; n = 6) was observed. The horizontal dashed line represents no change in EPSP amplitude, and the vertical dashed line represents the onset of the EPSP.

Second, we tested the requirement for postsynaptic bursting to induce a change in synaptic strength (Fig. 3A,B). The time interval Δt, defined as the time interval between the onset of the EPSP and the AP closest in time to the EPSP, was kept constant at Δt = −10 ms or Δt = +10 ms. Pairing an EPSP and one AP at Δt = +10 ms did not change the EPSP amplitude (1.04 ± 0.08; p > 0.5; n = 10), whereas the reverse order resulted in a decrease in EPSP amplitude (0.80 ± 0.07; p < 0.05; n = 5). A “minimal burst” of two APs (50 Hz) at Δt = +10 ms resulted in significant potentiation (1.95 ± 0.31; p < 0.05; n = 9). The reverse order (two APs and EPSP; Δt = −10 ms) resulted in depression (0.72 ± 0.12; p < 0.05; n = 5).

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Figure 3.

LTP and LTD dependence on the number of APs and AP frequency in the burst. A, Pooled and normalized EPSP amplitudes for different numbers of APs in the burst and a time interval between the AP closest to the EPSP and the onset of the EPSP of Δt = −10 ms and Δt = +10 ms. Insets depict the pairing protocol. Pairing an EPSP with a single AP at Δt = +10 ms had no effect on EPSP amplitude. The sequence of AP and EPSP at Δt = −10 ms resulted in depression. An EPSP paired with a burst of two APs (50 Hz) at Δt = +10 ms resulted in potentiation. Two APs (50 Hz) preceding the EPSP resulted in depression of the EPSP amplitude. B, LTP induction at Δt = +10 ms (open circles) depended on the number of APs that followed the EPSP, whereas LTD induction (open boxes) was correlated only weakly with the number of APs preceding the EPSP by Δt = −10 ms. The open diamond to the left corresponds to EPSP-only stimulation during the pairing period. Significant differences, *p < 0.05 and **p < 0.01. C, Pooled and normalized EPSP amplitudes for different AP frequencies in the burst and a time interval between the AP closest to the EPSP and the onset of the EPSP of Δt = −10 ms and Δt = +10 ms. Pairing an EPSP with a burst of three APs at 20 Hz did not result in significant potentiation. A burst of three APs at 20 Hz preceding an EPSP resulted in depression. Pairing an EPSP with a burst of three APs at 100 Hz that followed at Δt = +10 ms resulted in strong potentiation. A burst of three APs at 100 Hz preceding the EPSP resulted in depression. D, Summary plot of the change in EPSP amplitude versus the AP frequency in a burst of three APs. The induction of LTP is frequency-dependent (open circles), whereas LTD induction did not depend on the burst frequency. The dashed lines indicate no change in EPSP amplitude.

Synaptic stimulation without pairing with postsynaptic APs (EPSPs only) did not result in a change in EPSP amplitude (0.97 ± 0.08; p > 0.5; n = 5). Similarly, a burst of three APs at 50 Hz without pairing with an EPSP (three APs only) had no effect (1.05 ± 0.2; p > 0.9; n = 6).

Last, we varied the AP frequency in a burst of three APs between 20 and 100 Hz (Fig. 3C,D). A burst of three APs at 20 Hz that followed the EPSP by Δt = +10 ms had no effect on the EPSP amplitude after pairing (1.09 ± 0.27; p > 0.5; n = 5). A burst at 20 Hz preceding the EPSP by Δt = −10 ms resulted in depression (0.72 ± 0.14; p < 0.05; n = 7). A burst of three APs at 100 Hz that followed the EPSP by Δt = +10 ms induced strong potentiation (2.29 ± 0.48; p < 0.01; n = 7), whereas a burst of three APs at 100 Hz preceding the EPSP by Δt = −10 ms resulted in depression (0.52 ± 0.12; p < 0.05; n = 4).

From these results we conclude that LTP and LTD depend on the timing between the AP burst and onset of the compound EPSP. The induction of LTD is less sensitive to the properties of the burst, whereas LTP requires at least a burst of two APs at frequencies >20 Hz. These results indicate that small variations in postsynaptic AP firing with respect to a synaptically evoked EPSP can result in different directions of the change in synaptic strength.

LTP and LTD are equally sensitive to fast and slow Ca²⁺ buffers

Changes in synaptic strength depend on a transient [Ca²⁺]_i elevation in the dendrites of the postsynaptic neuron. It is, however, unclear whether a putative “Ca²⁺ sensor” that may trigger the induction of changes in synaptic strength is sensitive to global, volume-averaged [Ca²⁺]_i or whether it is sensitive to local [Ca²⁺]_i transients in Ca²⁺ microdomains around sources of Ca²⁺ influx (Franks and Sejnowski, 2002). One way to differentiate between global and local [Ca²⁺]_i signaling is to load the postsynaptic cell with different Ca²⁺ buffers, such as EGTA or BAPTA. These have a similar affinity (K_D ≈ 200 nm) but faster (BAPTA) or slower (EGTA) equilibration kinetics.

Loading cells with EGTA or BAPTA at 2 mm was sufficient to block LTP induction (relative magnitude of LTP with EGTA: −0.05 ± 0.18, p > 0.7, n = 6; BAPTA: −0.16 ± 0.14, p > 0.7, n = 5) (Fig. 4A). Lower concentrations of EGTA and BAPTA blocked LTP induction less (0.5 mm EGTA: 0.64 ± 0.20, p < 0.05, n = 6; 0.5 mm BAPTA: 0.63 ± 0.3, p < 0.05, n = 6). A sigmoid fit to the concentration dependence indicated a half-effective concentration for blocking LTP of 0.6 mm for EGTA and 0.5 mm for BAPTA (Fig. 4B).

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Figure 4.

LTP and LTD are equally sensitive to fast and slow Ca²⁺ buffers. A, Buffering of postsynaptic Ca²⁺ with 2 mm EGTA (open circles) or 2 mm BAPTA (filled circles) blocked the induction of LTP by the sequence of an EPSP and three APs (50 Hz) at Δt = +10 ms. A lower concentration of EGTA or BAPTA of 0.5 mm blocked 40% of LTP. B, Titration curve for different concentrations of EGTA (open circles) and BAPTA (filled circles) and their effects on the induction of LTP. Data were normalized to the change in EPSP amplitude for no buffer added. The slow Ca²⁺ buffer EGTA blocked LTP with the same concentration dependence as the fast Ca²⁺ buffer BAPTA. A sigmoidal fit yielded a half-concentration of 0.6 and 0.5 mm for EGTA (gray line) and BAPTA (black line), respectively. C, A concentration of 1 mm EGTA (open squares) or BAPTA (filled squares) was sufficient to blocked the induction of LTD by the sequence of three APs (50 Hz) and an EPSP at Δt = −10 ms. A lower concentration of EGTA or BAPTA of 0.25 mm had no significant effect on the induction of LTD. D, Titration curve for different concentrations of EGTA (open boxes) and BAPTA (filled boxes) and their effect on the induction of LTD. Data were normalized to the change in EPSP amplitude for no buffer added. A sigmoidal fit yielded a half-concentration of 0.39 and 0.36 mm for EGTA (gray line) and BAPTA (black line), respectively. The dashed lines indicate no change in EPSP amplitude.

LTD induction was blocked completely by 1 mm EGTA (relative magnitude of LTD, −0.2 ± 0.25; p > 0.3; n = 3) (Fig. 4C), whereas 0.25 mm EGTA blocked LTD induction correspondingly less (−0.86 ± 0.35; p < 0.05; n = 6). BAPTA (1 mm) also blocked LTD induction completely (−0.09 ± 0.51; p > 0.5; n = 7), and 0.25 mm BAPTA blocked LTD induction less (0.92 ± 0.2; p < 0.05; n = 6). The half-effective concentration for the block of LTD was 0.39 mm by EGTA and 0.36 mm by BAPTA (Fig. 4D).

We conclude that postsynaptic elevation of [Ca²⁺]_i is necessary for the induction of both LTP and LTD. The comparable concentration dependence of BAPTA and EGTA in blocking the induction or expression of potentiation or depression suggests that the putative Ca²⁺ sensor or sensors that trigger long-lasting changes in synaptic efficacy respond to the volume-averaged increase in [Ca²⁺]_i. Either they are separated by a relatively large distance from the site of Ca²⁺ influx (Neher, 1998; Augustine et al., 2003) or they have slower Ca²⁺-binding kinetics than EGTA.

Ca²⁺ transients in spines evoked during STDP induction protocols

The results described above suggested that the induction of synaptic potentiation and depression depended on a rise in postsynaptic [Ca²⁺]_i, presumably in dendritic spines. We used two-photon excitation fluorescence microscopy (Denk et al., 1990) to measure the [Ca²⁺]_i transients in single spines evoked during the stimulation patterns described above (Fig. 5A–C).

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Figure 5.

[Ca²⁺]_i transients in single spines evoked by pairing protocols. A, Two-photon fluorescence image of a L2/3 pyramidal neuron overlaid with the simultaneously acquired IR image. The region indicated by the dashed box is shown on an expanded scale in B. B, Fluorescence image of a spine responding with a [Ca²⁺]_i transient to synaptic stimulation. The dashed line indicates the position of the line scan. An example line scan during a synaptically evoked EPSP paired with three APs (50 Hz) at Δt = +10 ms is shown in the bottom image. The green fluorescence of the Ca²⁺-sensitive indicator Oregon Green BAPTA-6F (500 μm) is overlaid with the red fluorescence from the Ca²⁺-insensitive dye Alexa 594 (50 μm). Stimulation begins 50 ms after the beginning of the recording. The bar at the top of the line scan indicates the region of interest over which fluorescence was averaged for each time point. C, Somatic voltage recordings (top traces) and the corresponding [Ca²⁺]_i transients (bottom traces) for an EPSP, three APs, three APs (50 Hz) and an EPSP at Δt′ = −50 ms, and an EPSP and three APs (50 Hz) at Δt′ = +10 ms. The solid gray lines are exponential fits to the decay phase of the [Ca²⁺]_i transient yielding the peak amplitude (ΔG/R)_max. D, Peak amplitude (top graph) and nonlinearity factor (bottom graph) plotted for the time intervals Δt′. The dashed line indicates linear summation of the [Ca²⁺]_i transients. Significant differences, *p < 0.05 and **p < 0.01. E, Peak amplitude (top graph) increases linearly with the number of APs in the burst for APs only (triangles), an EPSP and APs (50 Hz) at Δt = +10 ms (circles), and the sequence of APs (50 Hz) and an EPSP at Δt = −10 ms (boxes). The diamond to the left indicates the peak amplitude for the EPSP-evoked [Ca²⁺]_i transient. The nonlinearity factor (bottom graph) does not depend on the number of APs in the burst, but it depends on the relative timing between the EPSP and APs. APs that follow the EPSP by Δt = +10 ms result in supralinear summation of the [Ca²⁺]_i transients, whereas APs preceding the EPSP by Δt = −10 ms result in linear summation. F, Peak amplitude (top graph) increases linearly with the frequency in a burst of three APs for APs only (triangles), an EPSP and APs at Δt = +10 ms (circles), and the sequence of APs and an EPSP at Δt = −10 ms (boxes). The nonlinearity factor (bottom graph) indicates linear summation of the [Ca²⁺]_i transients for APs preceding the EPSP, independent of AP frequency and supralinear summation of [Ca²⁺]_i transients for APs that follow the EPSP for frequencies >20 Hz.

First, varying the time interval Δt′ between an EPSP and a burst of three APs (50 Hz) allowed us to map the peak [Ca²⁺]_i amplitude and the “nonlinearity” factor (peak [Ca²⁺]_i amplitude, normalized to the expected linear sum of EPSP-evoked and AP-evoked [Ca²⁺]_i transients) (Nevian and Sakmann, 2004) for the time intervals relevant for the induction of changes in synaptic strength (Fig. 5D). The plot of the peak [Ca²⁺]_i amplitude for different time intervals Δt′ revealed that pairing an EPSP with three APs at Δt′ = +10 ms resulted in a significantly larger [Ca²⁺]_i transient than pairing an EPSP with three APs at the other time intervals that were tested (p < 0.01; n = 4–39; ANOVA; Newman–Keuls). These other pairing protocols evoked [Ca²⁺]_i transients with similar peak [Ca²⁺]_i amplitudes (p > 0.2; n = 4–34; ANOVA; Newman–Keuls). The summation of the Ca²⁺ signals showed linear or supralinear summation, depending on the timing interval Δt′, similar to other types of cortical cells (Köster and Sakmann, 1998; Nevian and Sakmann, 2004). Pairing an EPSP with three APs at Δt′ = −10, +10, and +50 ms resulted in supralinear summation, with the largest degree of supralinearity for Δt′ = +10 ms (nonlinearity factor of 1.8 ± 0.1; p < 0.01; n = 39). Pairing at Δt′ = −30, −50, and −90 ms did not deviate significantly from linear summation of the Ca²⁺ signals (p > 0.1; n = 4–21).

Second, peak amplitude and nonlinearity of summation were analyzed as a function of the number of APs in a burst for a frequency of 50 Hz and a given time interval (Δt = −10 ms and Δt = +10 ms) between EPSP and AP burst. Peak amplitudes increased linearly with the number of APs for all of the stimulation protocols that were tested (linear regression lines, r² > 0.98) (Fig. 5E). The summation of the Ca²⁺ signals was approximately twofold larger than the linear sum for stimulation protocols in which the APs followed the EPSP by Δt = +10 ms, independent of the number of APs in the burst (p < 0.01; n = 7–39). The summation of the Ca²⁺ signals for stimulation protocols in which the APs preceded the EPSP was independent of the number of APs in the burst and not different from linear summation (p > 0.5; n = 5–21).

Third, the peak [Ca²⁺]_i amplitude increased linearly as a function of AP frequency in a burst of three APs for all of the stimulation protocols that were tested (Fig. 5F). The summation of the Ca²⁺ signals was larger than the expected linear sum for stimulation protocols in which the burst followed the EPSP by Δt = +10 ms with burst frequencies >20 Hz. The summation of the Ca²⁺ signals for stimulation protocols in which the burst preceded the EPSP was independent of the frequency of APs in the burst and not different from the expected linear sum (p > 0.5; n = 3–21).

Dependence of LTP and LTD induction on Ca²⁺ influx via NMDA receptors and VDCCs

The asymmetry in the peak [Ca²⁺]_i amplitude timing curve (Fig. 5D) presumably is caused by the coincident activation of the NMDA receptor (NMDAR) channel after binding of glutamate and relief of the Mg²⁺ block caused by membrane depolarization attributable to backpropagating APs (Yuste and Denk, 1995; Köster and Sakmann, 1998; Nevian and Sakmann, 2004). We used the protocols consisting of an EPSP and three APs (50 Hz) at Δt = −10 ms and Δt = +10 ms to test the requirement of NMDAR activation for the timing-dependent difference in the Ca²⁺ signals and for the induction of potentiation and depression (Fig. 6). Bath application of the NMDAR antagonist d-APV (50 μm) significantly reduced the peak [Ca²⁺]_i amplitude for both time intervals (reduction to 33 ± 9% for Δt = +10 ms, p < 0.05; n = 4 and reduction to 45 ± 19% for Δt = −10 ms, p < 0.05; n = 4). The [Ca²⁺]_i transients were reduced to the level of AP-evoked Ca²⁺ influx, abolishing the timing dependence (Fig. 6B,C). Bath application of d-APV abolished potentiation and depression (Δt = +10 ms: 1.08 ± 0.11, p > 0.1, n = 3; Δt = −10 ms: 0.98 ± 0.11, p > 0.5, n = 6), indicating that NMDAR activation was necessary for the induction of LTP and LTD (Fig. 6D,E). The induction of spike-timing-dependent LTD, but not LTP, might be mediated by the activation of presynaptic NMDARs (Sjostrom et al., 2003; Bender et al., 2006). Postsynaptic NMDARs can be blocked specifically by loading the postsynaptic cell with MK-801 (1 mm), an open channel blocker for NMDARs, through the patch pipette. The induction of LTP was abolished (0.95 ± 0.19; p > 0.5; n = 6) with MK-801 present in the intracellular solution, similar to bath application of d-APV (Fig. 6F,H). In contrast, intracellular MK-801 had no effect on the induction of LTD (0.60 ± 0.11; p < 0.05; n = 7) (Fig. 6G,I). Therefore, we conclude that the induction of LTP depends on a large postsynaptic Ca²⁺ influx through NMDARs, whereas AP burst-pairing-induced LTD is independent of postsynaptic activation of NMDARs. In the latter case Ca²⁺ influx through VDCCs is presumably sufficient to induce LTD (Fig. 6B).

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Figure 6.

The contribution of NMDARs to Ca²⁺ signaling and synaptic plasticity. A, Fluorescence image of a spine responding with a [Ca²⁺]_i transient to synaptic stimulation. The dashed line indicates the position of the line scan. B, [Ca²⁺]_i transients for the sequence of an EPSP and three APs (50 Hz) for Δt = +10 ms (top trace) and Δt = −10 ms (bottom trace) for control (gray trace) and after the bath application of the NMDAR blocker d-APV (50 μm; black trace). C, Average peak amplitudes for pairing an EPSP with three APs (50 Hz) at Δt = −10 ms and Δt = +10 ms for control (gray circles) and after the bath application of d-APV (black circles). d-APV significantly reduced the peak amplitude for both time intervals (*p < 0.05; n = 3). D, Normalized EPSP amplitude over time for the pairing protocol of an EPSP and three APs (50 Hz) at Δt = +10 ms in the presence of d-APV (bath application). LTP induction was abolished for Δt = +10 ms. Dashed lines indicate no change in EPSP amplitude. E, Bath application of d-APV also abolished the induction of LTD for Δt = −10 ms. F, Intracellular application of the open NMDAR channel blocker MK-801 (1 mm) blocked the induction of LTP. G, In contrast, intracellular application of MK-801 had no effect on the induction of LTD. H, Either bath application of d-APV or intracellular application of MK-801 blocked the induction of LTP by the pairing protocol of an EPSP and three APs (50 Hz) at Δt = +10 ms (p > 0.3; n = 3–6). I, Bath application of d-APV blocked the induction of LTD (p > 0.5; n = 6) by the pairing protocol of three APs (50 Hz) and an EPSP at Δt = −10 ms, whereas intracellular application of MK-801 had no effect on LTD (*p < 0.05; n = 7).

L-VDCCs might control the induction of changes in synaptic strength (Magee and Johnston, 1997, 2005). Therefore, we tested the contribution of L-VDCCs on the [Ca²⁺]_i transients evoked by the protocols consisting of an EPSP and three APs (50 Hz) at Δt = −10 ms and Δt = +10 ms (Fig. 7A–C). Bath application of the L-VDCC blocker nimodipine (10 μm) had no effect on the [Ca²⁺]_i transient evoked by pairing an EPSP and three APs at Δt = +10 ms. For the sequence of three APs and an EPSP at Δt = −10 ms, nimodipine significantly reduced the peak [Ca²⁺]_i amplitude to 69 ± 1% of control (p < 0.05; n = 3). Next we tested the effect of nimodipine on plasticity. Pairing an EPSP with three APs (50 Hz) at Δt = +10 ms had no effect on LTP induction in the presence of nimodipine (Fig. 7D). The potentiation of the EPSP amplitude was 1.92 ± 0.31 (p < 0.01; n = 7), similar to control. Nimodipine also had no effect on the induction of LTD (0.70 ± 0.10; p < 0.05; n = 8), corresponding to the only minor reduction of the [Ca²⁺]_i transient.

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Figure 7.

The contribution of VDCCs to Ca²⁺ signaling and synaptic plasticity. A, Fluorescence image of a spine responding with a [Ca²⁺]_i transient to synaptic stimulation. The dashed line indicates the position of the line scan. B, [Ca²⁺]_i transients for the sequence of an EPSP and three APs (50 Hz) for Δt = +10 ms (top trace) and Δt = −10 ms (bottom trace) for control (gray trace) and after the bath application of the L-VDCC blocker nimodipine (10 μm; black trace). C, Average peak amplitudes for pairing an EPSP with three APs (50 Hz) at Δt = −10 ms and Δt = +10 ms for control (gray circles) and after the bath application of nimodipine (black circles). Nimodipine significantly reduced the peak amplitude for Δt = −10 ms (*p < 0.05; n = 3) but had no effect on the peak amplitude for Δt = +10 ms. D, The L-VDCC blocker nimodipine had no effect on the induction of LTP. E, Nimodipine also had no effect on the induction of LTD. F, Blocking T-VDCCs with Ni²⁺ (50 μm) abolished the induction of LTD for the pairing protocol of one AP and an EPSP at Δt = −10 ms. G, In contrast, Ni²⁺ had no effect on the induction of LTD for the pairing protocol of three APs (50 Hz) and an EPSP at Δt = −10 ms. H, The sequence of three APs (50 Hz) and an EPSP for Δt = −10 ms evoked [Ca²⁺]_i transients in the spine, indicated in the fluorescence image by the dashed line under control conditions (gray trace) and a corresponding smaller [Ca²⁺]_i transient after the bath application of Ni²⁺ (black trace). I, Summary of LTD induction with pharmacological block of VDCCs. Ni²⁺ blocked the induction of LTD if one AP preceded the EPSP during pairing (p > 0.5; n = 3). Neither Ni²⁺ nor nimodipine alone had an effect on LTD induction if a burst of three APs (50 Hz) preceded the EPSP (*p < 0.05; n = 4–8). Bath application of nimodipine and Ni²⁺ together blocked LTD (p > 0.5; n = 3).

T-VDCCs have been suggested to be involved in spike-timing-dependent induction of LTD (Bender et al., 2006). Consistently, pairing one AP with an EPSP at Δt = −10 ms in the presence of Ni²⁺ abolished the induction of LTD (1.05 ± 0.16; p > 0.5; n = 3) (Fig. 7F). On the other hand, a burst of three APs (50 Hz) paired with an EPSP at Δt = −10 ms in the presence of Ni²⁺ resulted in LTD (0.70 ± 0.03; p < 0.05; n = 4) (Fig. 7G,I). Ni²⁺ reduced the [Ca²⁺]_i transient evoked in this case to 65 ± 12% (n = 3) of control (Fig. 7H). Bath application of nimodipine together with Ni²⁺ resulted in a block of LTD by pairing three APs (50 Hz) with an EPSP at Δt = −10 ms (1.00 ± 0.05; p > 0.5; n = 3) (Fig. 7I).

These experiments show that VDCCs are necessary for the induction of LTD. Single-spike LTD requires Ca²⁺ influx through T-VDCCs; however, during pharmacological block of these channels, bursts of APs evoke a Ca²⁺ influx via other subtypes, which is sufficiently large to induce LTD. Therefore, the requirement for a specific VDCC-subtype for the induction of LTD is masked by AP burst pairing.

Spine Ca²⁺ transients cannot account for the direction of changes in synaptic efficacy

The analysis of the peak [Ca²⁺]_i amplitude dependence on timing, number of APs, and frequency of APs suggested that pairing protocols, which induce either potentiation or depression, can raise [Ca²⁺]_i to the same volume-averaged level. Therefore, we compared the average peak [Ca²⁺]_i amplitude evoked by the different stimulation protocols to the average effect on long-term changes in synaptic efficacy. The resulting plot represented the average change in EPSP amplitude as a function of the average peak [Ca²⁺]_i amplitude that a spine on a basal dendrite encounters during the pairing period (Fig. 8). The data showed no correlation between the peak [Ca²⁺]_i amplitude and the direction of change in synaptic strength, because several stimulation protocols, which gave rise to similar peak [Ca²⁺]_i amplitudes, induced either LTP or LTD (Fig. 8, shaded area). Thus although a postsynaptic increase in [Ca²⁺]_i is necessary for the induction of changes in efficacy, the peak volume-averaged [Ca²⁺]_i amplitude is not a unique determinant for the selective induction and expression of bidirectional synaptic plasticity. Additional factors, independent of the Ca²⁺ signal, must contribute to the induction pathway. The observation that protocols in which the APs preceded the EPSP resulted in LTD whereas the reverse order resulted in LTP (Figs. 2G, 3B,D) led to the clustering of the data into two groups according to the timing of the EPSP and APs. The clustering of stimulation protocols in which the APs either preceded or followed the EPSP indicated that the induction of LTD and LTP were two differential processes, both of which were controlled separately by the peak [Ca²⁺]_i amplitude. Sigmoid fits to the two groups of data showed a high correlation between the induction of either LTD or LTP and the peak [Ca²⁺]_i amplitude. The half-to-minimum value for the induction of LTD was (ΔG/R)_max = 0.07, and the half-to-maximum value for the induction of LTP was approximately twofold larger [(ΔG/R)_max = 0.13]. The stimulation patterns in which the EPSP was evoked within the burst of APs fell close to the fit of the Ca²⁺ dependence for the LTP group, indicating that the induction of LTD can be blanked by APs that follow the AP–EPSP sequence.

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Figure 8.

The peak [Ca²⁺]_i amplitude does not predict LTP or LTD. Summary plot of the average change in EPSP amplitude versus the average peak [Ca²⁺]_i amplitude expressed as (ΔG/R)_max. The change in EPSP amplitude is not a unique function of the peak [Ca²⁺]_i amplitude. Similar peak levels of [Ca²⁺]_i can result in either LTP or LTD (data points in shaded area). The clustering of induction protocols in which the APs either precede the EPSP (open boxes) or follow the EPSP (open circles) indicate that the inductions of LTP and LTD are separate processes. Fitting sigmoid functions to the data sets (solid blue line, APs following; solid green line, APs preceding) shows that LTP and LTD both depend on the peak [Ca²⁺]_i amplitude. The protocols in which APs preceded and followed the EPSP (red circles) fall close to the curve for the Ca²⁺ dependence of LTP.

We conclude that the induction of LTP and LTD is controlled differentially by the elevation of [Ca²⁺]_i in the postsynaptic spine. The sequence of EPSP and postsynaptic APs seems to activate additional mechanisms, which determine the direction of the change in synaptic strength.

LTD requires activation of mGluRs

In hippocampal as well as in cortical neurons the induction of some forms of LTD is sensitive to the activation of mGluRs (Otani and Connor, 1998; Anwyl, 1999, 2006; Egger et al., 1999; Cho et al., 2001). We tested whether LTD induced by pairing three APs (50 Hz) with an EPSP at Δt = −10 ms required the activation of mGluRs. Bath application of the broadband mGluR antagonist MCPG (500 μm) resulted in a complete block of LTD (1.06 ± 0.16; p > 0.5; n = 7) (Fig. 9E). In contrast, MCPG had no effect on LTP induction by pairing an EPSP and three APs (50 Hz) at Δt = +10 ms (1.79 ± 0.33; p < 0.05; n = 9) (Fig. 9D). The [Ca²⁺]_i transients evoked by pairing an EPSP with three APs (50 Hz) at Δt = −10 ms and Δt = +10 ms were not different from control after the bath application of MCPG (p > 0.1; n = 4) (Fig. 9A–C), indicating that mGluRs had no direct effect on the [Ca²⁺]_i transients (Brenowitz and Regehr, 2005) and that the block of LTD was attributable to inactivation of a G-protein-coupled signaling cascade (Piomelli, 2003).

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Figure 9.

Effect of the mGluR blocker MCPG on [Ca²⁺]_i transients and synaptic plasticity. A, Two-photon image of an active synaptic spine. The dashed line indicates the position of the line scan. B, [Ca²⁺]_i transients for the sequences of an EPSP and three APs (50 Hz) at Δt = +10 ms (top traces), three APs (50 Hz) and an EPSP at Δt = −10 ms (middle traces), and three APs (100 Hz) and an EPSP at Δt = −10 ms (bottom traces) for control (gray traces) and after bath application of the mGluR blocker MCPG (500 μm; black traces). The fluorescence traces in the presence of MCPG do not differ from control. C, Summary plot of the peak [Ca²⁺]_i amplitudes for control versus peak [Ca²⁺]_i amplitude after the bath application of MCPG. The points for the stimulation protocols depicted in B fall close to the unity line (dashed line), indicating no significant effect of MCPG on the peak amplitude of the [Ca²⁺]_i transients. D, Summary of normalized EPSP amplitudes for pairing an EPSP with three APs (50 Hz) at Δt = +10 ms under control conditions (gray trace) and for experiments in MCPG (black trace). LTP induction in the presence of MCPG was not different from control. Dashed lines indicate no change in EPSP amplitude. E, Summary of normalized EPSP amplitudes for pairing three APs (50 Hz) with an EPSP at Δt = −10 ms under control conditions (gray trace) and for experiments in MCPG (black trace). LTD was abolished in this case. F, Summary of normalized EPSP amplitudes for pairing three APs (100 Hz) with an EPSP at Δt = −10 ms under control conditions (gray trace) and for experiments in MCPG (black trace). The LTD under control conditions was reversed to LTP by MCPG. G, Summary plot of change in EPSP amplitude for the pairing protocols depicted in B as a function of peak [Ca²⁺]_i amplitude under control conditions (gray) and in the presence of MCPG (black). In the presence of MCPG no LTD is induced, and the change in EPSP amplitude becomes a monotonically increasing function of the peak [Ca²⁺]_i amplitude.

The LTD-inducing protocol of three APs (100 Hz) paired with an EPSP at Δt = −10 ms evoked [Ca²⁺]_i transients, which had a peak amplitude comparable to protocols that induced LTP. Bath application of MCPG also had no effect on the [Ca²⁺]_i transient in this case (88 ± 6% of control; p > 0.1; n = 4). Surprisingly, pairing three APs (100 Hz) with an EPSP at Δt = −10 ms in the presence of MCPG resulted in the induction of LTP (1.53 ± 0.24; p < 0.05; n = 11) instead of inducing LTD, as under control conditions (Fig. 9F). We conclude that the activation of mGluRs is necessary for the induction of LTD. If the mGluR-dependent pathway is blocked, LTP can be induced, depending on the peak [Ca²⁺]_i amplitude (Fig. 9G).

Signaling pathway for the induction of LTD

Next we investigated the downstream signaling cascade involved in the induction of LTD after mGluR activation. One product of this cascade is the synthesis of endocannabinoids, which can act as retrograde messengers, resulting in a decrease in synaptic efficacy (Sjostrom et al., 2003, 2004). The endocannabinoid 2-arachidonoylglycerol (2-AG) is synthesized via a PLC and diacylglycerol (DAG) lipase-dependent pathway. Bath application of the CB1 receptor antagonist AM251 (2 μm) resulted in the block of LTD by the protocol consisting of three APs (50 Hz) and an EPSP at Δt = −10 ms (1.09 ± 0.14; p > 0.5; n = 5), suggesting the involvement of endocannabinoid signaling (Fig. 10E). The PLC inhibitor U73122 (5 μm) also blocked LTD (1.11 ± 0.07; p > 0.1; n = 4) without any effect on the [Ca²⁺]_i transient evoked by the sequence of three APs (50 Hz) and an EPSP at Δt = −10 ms (99 ± 11% of control; n = 4) (Fig. 10A,B).

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Figure 10.

Signaling pathway for the induction of LTD. A, Summary of normalized EPSP amplitudes for pairing three APs (50 Hz) with an EPSP at Δt = −10 ms in the presence of the PLC blocker U73122 (5 μm). U73122 blocked the induction of LTD. B, Two-photon image of an active spine. The dashed line indicates the position of the line scan. U73122 had no effect on the [Ca²⁺]_i transients evoked by the sequence of three APs (50 Hz) and an EPSP at Δt = −10 ms (black trace) as compared with control (gray trace). C, Heparin (400 U/ml), a blocker of Ca²⁺ release from internal stores mediated by IP₃ receptors, had no effect on the induction of LTD. D, Amplitude of averaged peak [Ca²⁺]_i transients measured during the induction of LTD with the protocol of three APs (50 Hz) and an EPSP at Δt = −10 ms under control conditions. Every sixth transient was recorded during the 10 min (0.1 Hz) induction period. No correlation between the peak amplitude and the number of stimuli was found (linear correlation, r² = 0.2; n = 7). E, Bath application of the CB1 receptor antagonist AM251 (2 μm) blocked the induction of LTD. F, Summary of the signaling pathway for the induction of LTD. Block of PLC and CB1 receptors abolished the induction of LTD (p > 0.1; n = 4–5), whereas the block of Ca²⁺ release from internal stores had no effect on the induction of LTD (*p < 0.05; n = 9). Dashed lines represent no change in EPSP amplitude.

A side product of the synthesis of DAG by PLC is IP₃, which could result in the release of Ca²⁺ from internal stores. The observation that neither the block of mGluRs nor the block of PLC resulted in a significant change in the spine [Ca²⁺]_i transients suggested that release from internal stores did not contribute to the [Ca²⁺]_i transients that were required for the induction of LTD by a short burst of APs preceding synaptic activation.Another possibility might be that the concentration of IP₃ within the spine gradually increases during the 60 pairings, resulting in Ca²⁺ release from internal stores only for later pairings. We recorded the [Ca²⁺]_i transients in a spine evoked by three APs (50 Hz) and an EPSP at Δt = −10 ms during the pairing period. No correlation between the peak [Ca²⁺]_i amplitude and the number of pairings was found (r² = 0.2; n = 7), suggesting that the recorded spine [Ca²⁺]_i transients did not change significantly during the pairing period (Fig. 10D). Finally, blocking IP₃-dependent release of Ca²⁺ from internal stores by intracellular application of heparin (400 U/ml) through the patch pipette had no effect on LTD (0.68 ± 0.12; p < 0.05; n = 9) (Fig. 10C). The resulting pharmacological signature for LTD (Fig. 10F) suggests retrograde endocannabinoid signaling, mediated by G-coupled mGluR and PLC activation.