Associative Long-Term Depression in the Hippocampus Is Dependent on Postsynaptic N-Type Ca2+ Channels

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The Journal of Neuroscience, November 15, 2000, 20(22):8290-8297

Associative Long-Term Depression in the Hippocampus Is Dependent on Postsynaptic N-Type Ca²⁺ Channels
Claus Normann¹^,², Diana Peckys¹, Christian H. Schulze¹, Jörg Walden², Peter Jonas¹, and Josef Bischofberger¹
¹ Institute of Physiology, University of Freiburg, D-79104 Freiburg, Germany, and ² Department of Psychiatry, University of Freiburg, D-79104 Freiburg, Germany

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Long-term depression (LTD) is a form of synaptic plasticity that can be induced either by low-frequency stimulation of presynapticfibers or in an associative manner by asynchronous pairing ofpresynaptic and postsynaptic activity. We investigated the inductionmechanisms of associative LTD in CA1 pyramidal neurons of thehippocampus using whole-cell patch-clamp recordings and Ca²⁺ imaging in acute brain slices. Asynchronous pairing of postsynapticaction potentials with EPSPs evoked with a delay of 20 msec induceda robust, long-lasting depression of the EPSP amplitude to 43%.Unlike LTD induced by low-frequency stimulation, associative LTDwas resistant to the application of D-AP-5, indicating that itis independent of NMDA receptors. In contrast, associative LTDwas inhibited by (S)- $alpha$ -methyl-4-carboxyphenyl-glycine, indicatingthe involvement of metabotropic glutamate receptors. Furthermore,associative LTD is dependent on the activation of voltage-gatedCa²⁺ channels by postsynaptic action potentials. Both nifedipine,an L-type Ca²⁺ channel antagonist, and $omega$ -conotoxin GVIA, a selective N-typechannel blocker, abolished the induction of associative LTD. 8-hydroxy-2-dipropylaminotetralin(OH-DPAT), a 5-HT_1A receptor agonist, inhibited postsynaptic Ca²⁺ influx through N-type Ca²⁺ channels, without affecting presynaptic transmitter release.OH-DPAT also inhibited the induction of associative LTD, suggestingthat the involvement of N-type channels makes synaptic plasticityaccessible to modulation by neurotransmitters. Thus, the modulationof N-type Ca²⁺ channels provides a gain control for synaptic depression in hippocampalpyramidalneurons.

Key words: associative long-term depression; hippocampus; N-type Ca²⁺ channels; NMDA receptors; metabotropic glutamate receptors; asynchronous pairing

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Long-term changes in synaptic strength at glutamatergic synapses are thought to underlie complex functions of neuronal networks,such as learning and memory (Bliss and Collingridge, 1993). Thefrequency of synaptic stimulation determines both the extent andthe direction of the change in synaptic efficacy; high-frequencystimulation (HFS) leads to long-term potentiation (LTP), whereaslow-frequency stimulation (LFS) results in long-term depression(LTD) (Dudek and Bear, 1992). Whereas several molecular stepsof the induction and expression of LTP have been identified, themechanisms that lead to LTD are lessclear.

In the hippocampus, LFS induces two distinct forms of LTD, which depend either on the Ca²⁺ influx through NMDA receptors (NMDARs) (Mulkey and Malenka, 1992)or on the activation of metabotropic glutamate receptors (mGluRs)(Bolshakov and Siegelbaum, 1994; Oliet et al., 1997; Otani andConnor, 1998). The mGluR LTD appears to be the predominant formin young animals (postnatal days 3-8; Bolshakov and Siegelbaum,1994), whereas NMDAR LTD and mGluR LTD coexist in older animals(Heynen et al., 1996; Oliet et al., 1997; Otani and Connor, 1998).

Although LFS induces robust changes in synaptic strength, the situation that leads to the induction of hippocampal LTD invivo could be more complex. CA3 and CA1 pyramidal neurons generateaction potentials in a precise temporal relationship, dependingon the behavioral context (O'Keefe and Reece, 1993), i.e., pyramidalcells in the center of their place field fire action potentialsmore early in the theta cycle than neurons with adjacent placefields (Skaggs et al., 1996). Thus, the natural paradigm for LTPand LTD induction is likely to be associative, requiring the temporalcoincidence of synaptic activation and backpropagating actionpotentials (for review, see Linden, 1999). Indeed associativeLTD in the hippocampus can be induced by asynchronous pairingof presynaptic and postsynaptic activity (Levy and Steward, 1983;Stanton and Sejnowski, 1989; Stanton et al., 1991). However, theinduction mechanisms of associative LTD have remained controversial.Associative LTD in acute slices was reported to be independentof NMDARs (Stanton and Sejnowski, 1989). The opposite was shownfor associative LTD in organotypic cell culture (Debanne et al.,1994). Finally, in dissociated hippocampal cell culture, the associativeLTD appeared to be dependent on both Ca²⁺ influx through NMDARs and L-type Ca²⁺ channels (Bi and Poo, 1998).

Here we investigated the conditions necessary for the induction of associative LTD in acute hippocampal slices by asynchronousparing of presynaptic and postsynaptic activity at the Schaffercollateral-CA1 pyramidal cell synapse. The results suggest thatassociative LTD is dependent on both mGluRs and Ca²⁺ influx through voltage-gated L- and N-type Ca²⁺ channels. As N-type Ca²⁺ channels are preferential targets of G-protein-mediated neuromodulation(Hille, 1994), we have tested whether the modulation of postsynapticN-type Ca²⁺ channels could affect LTD induction, which would provide a novelmechanism to regulate activity-dependent synaptic plasticity inthehippocampus.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Slice preparation. Transverse 300-µm-thick slices were cut from the hippocampus of 11- to 22-d-old Wistar rats with a vibratome(DTK-1000; Dosaka, Kyoto, Japan). For most experiments 14- to18-d-old animals were used. The animals were killed by decapitation,in accordance with national and institutional guidelines. Sliceswere kept at 35°C for 30 min after slicing and then at room temperaturein physiological extracellular saline containing (in mM): 125NaCl, 25 NaHCO₃, 25 glucose, 2.5 KCl, 1.25 NaH₂PO₄, 2 CaCl₂, and1 MgCl₂, bubbled with carbogene (95% O₂ and 5% CO₂).

Electrophysiology. The slices were transferred to the recording chamber and continuously superfused with saline at a flowrate of 5-10 ml/min (chamber volume, ~2 ml). CA1 pyramidal neuronswere identified by their location using infrared differentialinterference contrast video microscopy and their characteristicfiring frequency adaptation during long depolarizing current pulses.Patch pipettes were pulled from borosilicate glass tubing (2.0mm outer diameter, 0.5 mm wall thickness; Hilgenberg, Malsfeld,Germany) and heat-polished immediately before use. An Axopatch200A amplifier (Axon Instruments, Foster City, CA) or an EPC-9amplifier (Heka, Lambrecht, Germany) were used for current-clamp(I-clamp fast) and voltage-clamp recordings. The Axopatch amplifierincluded a bridge-balance circuit for compensation of series resistancein the current-clamp mode, similar to that of the Axopatch 200B.Current and voltage signals were filtered at 5 and 10 kHz, respectively,with a 4-pole lowpass Bessel filter and digitized at 10 or 20kHz with a 1401plus interface (CED, Cambridge, UK). For data acquisitionand analysis we used self-made and commercial programs (EPC, CED;Pulse,Heka).

For current-clamp recordings the patch pipettes were filled with an internal solution containing (in mM): 135 K-gluconate,20 KCl, 2 MgCl₂, 2 Na₂ATP, 0.3 NaGTP, 0.2-0.5 EGTA, and 10 HEPES(pH was adjusted to 7.3 with KOH). Dendritic recordings were performedas described previously (Bischofberger and Jonas, 1997). Patchpipette resistance was 5-10 M $Omega$ for somatic and 10-12 M $Omega$ for dendriticrecordings. Bridge balance was used to compensate the series resistanceof 20-60 M $Omega$ .

Presynaptic Schaffer collateral fibers were stimulated using a stimulus isolator (List, Darmstadt, Germany) and a patch pipettewith a resistance of 1-3 M $Omega$ when filled with HEPES-buffered Na⁺-rich solution. The stimulus pipette was placed in the stratumradiatum of the CA1 region 20-50 µm away from the pyramidal celllayer. Two hundred microsecond voltage pulses of 10-80 V wereapplied to evoke subthreshold EPSPs at a frequency of 0.1 Hz.Orthodromic stimulation was performed in >90% of the experiments,and antidromic stimulation was performed in <10%, without obviousdifferences concerning basal transmission and plasticity induction.The latency between the center of the stimulus artifact and theonset of the EPSP was 2.9 ± 0.1 msec (n = 53), indicating monosynaptictransmission. Picrotoxin (20-50 µM) was present in the externalsolution of all current-clamp experiments. In some experiments10 µM glycine was added to the bath solution, with no obviousdifferences in theresults.

To record Ba²⁺ currents, the recording pipettes (mostly 0.8-2 M $Omega$ ) were filled with a solution containing (in mM): 140 CsCl,2 MgCl₂, 2 Na₂ATP, 0.3 NaGTP, 10 EGTA, and 10 HEPES (pH adjustedto 7.3 with CsOH). The bath solution contained 140 NaCl, 2 tetraethylammoniumchloride (TEACl), 2 MgCl₂, 2 BaCl₂, 1 µM tetrodotoxin (TTX) and10 HEPES (pH adjusted to 7.4 with NaOH). Recordings were madein the voltage-clamp configuration with series resistance (R_s)compensation (nominally 80-90%, lag 20-100 µsec; R_s before compensation3-10 M $Omega$ ). Leak and capacitive currents were subtracted using aP/-4 protocol. For whole-cell voltage-clamp experiments we usedonly slices from 11- to 13-d-old animals. Thus the CA1 pyramidalcells had relatively short and thin dendrites, minimizing space-clampartifacts. Voltage-clamp and current-clamp recordings were madeat 22-24°C.

Data analysis and statistics. All values are given as mean ± SEM, error bars in the figures also represent SEM. The decaytime course of EPSPs was fit with a single exponential. To calculatethe mean EPSP peak amplitude, 10-15 consecutive EPSPs were averagedfrom each experiment shortly before and 15-20 min after the endof the induction protocol. The changes in the mean EPSP amplitudewere analyzed for each experiment, and statistical significancewas assessed by a two-tailed Wilcoxon test at the significancelevel (P) indicated. Traces shown in the figures represent averagesof 10-15 consecutive sweeps. Average EPSP amplitudes in amplitude-timeplots represent means from seven consecutiveEPSPs.

Fluorescence measurements. For the measurement of the intracellular Ca²⁺ signals we used 0.1 mM fura-2 (Molecular Probes, Eugene, OR)instead of EGTA in the pipette solution. Cells were loaded forat least 15-20 min in the whole-cell configuration before measurementswere started. The excitation light source (Polychrome II with75 W Xenon lamp; TILL Photonics, Munich, Germany) was coupledto the epifluorescent port of the microscope (Axioskop FS2, Zeiss;60× water immersion objective, Olympus Optical, Tokyo, Japan)via a light guide. To minimize bleaching, the light intensitywas reduced to 10%. The filter combination for excitation andemission comprised a beam splitter (BSP410) and emission filters(LWP420, KP600) from Delta Light & Optics (Lyngby, Denmark). Someexperiments were done with 0.1 mM Oregon Green (Oregon Green 488Bapta-1, Molecular Probes) instead of fura-2, using a filter combinationfrom Zeiss (FT510, LP 520) and an excitation light intensity of5%.

The fluorescence was measured with a backilluminated frame-transfer CCD camera (EBFT 512; Princeton Instruments). Images withfull spatial resolution were taken with exposure times of 5 sec.For high-speed Ca²⁺ measurements (100 Hz repetition rate) we usually defined threerectangular regions of interest (ROIs) of 5 × 5 µm at the somaand 5 × 20 µm at a proximal and distal part of the apical dendrite.The pixels included in the ROIs were binned on-chip and digitizedsubsequently by the controller (Micromax; 1 MHz; Princeton Instruments).The fluorescence signals were corrected for background, whichwas obtained from ROIs shifted by 10-15 µm with respect to theoriginal ROIs (Schiller et al., 1995).

Calibration of the Ca²⁺ measurements with fura-2. To convert the fluorescence signals into Ca²⁺ concentrations, we used the isosbestic ratioing method (Neherand Augustine, 1992; Schiller et al., 1995). The action potential-inducedfluorescence change was recorded at an excitation wavelength of380 nm. The isosbestic fluorescence was measured immediately beforeand after this sweep, using an excitation wavelength of 356 nm(the Ca²⁺-insensitive wavelength in our experimental conditions). The ratioof the background-corrected fluorescence signals R = F₃₅₆/F₃₈₀was calculated and converted into the Ca²⁺ concentration using the equation (Grynkiewicz et al., 1985):

where R_min is the ratio in Ca²⁺-free solution and R_max the ratio when fura-2 is completely saturated with Ca²⁺. These values were determined by recording from CA1 pyramidalcells with internal solutions containing either 30 mM EGTA (R_min= 0.70 ± 0.01; n = 5) or 50 mM CaCl₂ (R_max = 6.97 ± 0.06; n =5). K_eff was calculated according to Neher and Augustine (1992)as K_eff = K_d (R_max/R_min), with the dissociation constant K_d =250 nM (Schiller et al., 1995). The resting Ca²⁺ concentration was on average 47 ± 4 nM (n = 17) and 46 ± 5 nM(n = 17) at the soma and dendrite, respectively. The decay timecourse of the action potential-induced Ca²⁺ transients was fitted with the sum of two exponentials and theamplitude-weighted $tau$ was given. Traces in the figures representaverages of 5-10 consecutive sweeps with the fitted curvesuperimposed.

Ca²⁺ measurements with Oregon Green. To examine the effects of nifedipine on Ca²⁺ transients, which is a highly light-sensitive substance, we used0.1 mM Oregon Green instead of fura-2. This dye has two advantages:it can be excited with lower energy light in the visible wavelengthrange (at 480 nm) and has a higher quantum yield than fura-2.Thus, we could use a lower excitation intensity (5%). In theseexperiments the relative change in fluorescence intensity $Delta$ F/Fwas calculated after background subtraction. The decay time constantsof the dendritic fluorescence transients ( $tau$ = 834 ± 79 msec; 40-100µm; n = 14) were not significantly different from those measuredwith fura-2 ( $tau$ = 707 ± 41 msec; n = 17; p > 0.2). Although thismay suggest that $Delta$ F/F is linearly related to the Ca²⁺ concentration, we cannot exclude a partial saturation of OregonGreen. This would imply a slight underestimation of the Ca²⁺ transient and, hence, of the effect ofnifedipine.

Chemicals. 8-hydroxy-2-dipropylamino-tetralin (OH-DPAT), (S)- $alpha$ -methyl-4-carboxyphenyl-glycine (MCPG), and D( $-$ )-2-amino-5-phosphonopentanoicacid (D-AP-5) were obtained from Tocris, and TTX and $omega$ -conotoxinGVIA were obtained from Alomone (Jerusalem, Israel). All otherchemicals were from Merck, Sigma, Riedel-de Haen, or Gerbu. Stocksolutions were made in distilled water or dimethylsulfoxide (fornifedipine, concentration of dimethylsulfoxide in the final solution, $<=$ 0.1%). $omega$ -conotoxin GVIA was coapplied with 1 mg/ml bovine serumalbumin (BSA) to prevent unspecific binding of the peptide toxins.Agonists and antagonists were applied by bath perfusion with theexception of $omega$ -conotoxin GVIA. For this substance, the bath perfusionwas interrupted, and the toxin was applied manually in the recordingchamber with a pipette. Neither the interruption of the perfusionnor the application of extracellular solution alone with BSA viaa pipette had any effect on Ba²⁺ currents or basal synaptic transmission. Nifedipine was protectedfromlight.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Whole-cell current-clamp recordings from CA1 pyramidal cells were made, and EPSPs were evoked by electrical stimulation ofSchaffer collaterals (Fig. 1A). The cells were held at a membranepotential of $-$ 68 to $-$ 70 mV, near the average resting potential( $-$ 68.6 ± 0.3 mV; n = 58). A robust associative LTD was inducedby asynchronous pairing of extracellular Schaffer-collateral stimulationwith a short postsynaptic current injection generating an actionpotential 20 msec before the EPSP (Fig. 1A,B). Time intervalsof 10-20 msec have been shown to be maximally effective for theinduction of associative LTD (Levy and Steward, 1983; Markramet al., 1997; Bi and Poo, 1998). The pairing was repeated 360times at a frequency of 0.3 or 1 Hz. This asynchronous pairingstimulation (APS) reduced the EPSP amplitude to 42.7 ± 1.8% (n= 17; p < 0.001) of the control value, measured 15-20 min afterthe induction protocol (Fig. 1C,D). As shown in Figure 2, 360action potentials or EPSPs alone at 1 Hz did not induce significantalterations in EPSP amplitude (action potentials alone: 93.8 ±5.1%, n = 3; p > 0.5; EPSPs alone: 103.4 ± 4.9% of control EPSPamplitude, n = 3; p > 0.5). Thus, this form of LTD is associativeand dependent on the asynchronous activity of both presynapticand postsynaptic neurons.

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Figure 1. Associative LTD induced by asynchronous pairing of presynaptic and postsynaptic action potentials in CA1 pyramidal neurons. A, Current-clamp whole-cell recording from a CA1 pyramidal neuron. EPSPs were evoked by extracellular stimulation of the Schaffer collateral pathway with 200 µsec voltage pulses applied through the stimulation pipette (inset). The EPSP amplitude was significantly decreased by asynchronous pairing of presynaptic and postsynaptic activity. Traces shown were taken immediately before and 15 min after asynchronous pairing. B, For the APS, a single action potential was evoked in the postsynaptic CA1 pyramidal neuron by current injection (700 pA, 5 msec). Twenty milliseconds after the onset of the current injection, an EPSP was evoked. This pairing was repeated 360 times at a frequency of 0.3 or 1 Hz. C, The EPSP amplitude during a single representative experiment is plotted against time. D, The mean EPSP amplitude is plotted against time (n = 17). The APS induction paradigm was applied at the time indicated by the arrow.

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Figure 2. Postsynaptic action potentials or EPSPs alone are not sufficient to induce LTD. A, The mean EPSP amplitude is plotted against time. Three hundred sixty action potentials were evoked in the postsynaptic cell at a frequency of 1 Hz from a membrane potential of $-$ 70 mV. This protocol did not change the EPSP amplitude (n = 3). B, Three hundred sixty EPSPs at a membrane potential of $-$ 70 mV, as shown in the inset, evoked at a frequency of 1 Hz did not change the EPSP amplitude (n = 3). The induction paradigms were applied at the times indicated by the arrows. Insets represent the first three sweeps of the induction paradigm of a representative experiment.

Associative LTD is dependent on metabotropic glutamate receptors

To investigate the induction mechanisms of associative LTD, we first examined the contribution of metabotropic glutamate receptors(Fig. 3A). In the presence of 500 µM MCPG, an antagonist of metabotropicglutamate receptors, the induction of associative LTD was inhibited(105.3 ± 3.6% of control EPSP amplitude, n = 6; p > 0.1). By contrast,the NMDAR antagonist D-AP-5 (50 µM) was without effect on thesynaptic depression (Fig. 3B). In the presence of D-AP-5, theEPSP amplitude was depressed to 45.5 ± 3.5% (n = 6; p < 0.001),similar to the control condition. In addition, D-AP-5 had no significanteffects on EPSP peak amplitude (8.6 ± 1.2 mV in control solutionvs 8.5 ± 1.2 mV in D-AP-5, n = 11; p > 0.5) and EPSP decay timeconstant (11.0 ± 11.1% decrease, n = 11; p > 0.05). These resultsare consistent with a minimal contribution of NMDARs to basalsynaptic transmission in CA1 pyramidal cells near the restingmembrane potential (Herron et al., 1986; Cash and Yuste, 1999).Thus, under our experimental conditions the NMDARs do not significantlycontribute to both basal synaptic transmission and induction ofassociative LTD.

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Figure 3. Associative LTD is dependent on activation of metabotropic glutamate receptors. A, The mean EPSP amplitude is plotted against time. In the presence of 500 µM MCPG, an antagonist of metabotropic glutamate receptors, the associative LTD was inhibited (n = 6). B, The NMDAR antagonist D-AP-5 (50 µM) was without effect on both basal synaptic transmission and the induction of associative LTD (n = 6). C, Nine hundred EPSPs at a membrane potential of $-$ 62 mV (inset), evoked at a frequency of 1 Hz (indicated by the arrow) reliably depressed the EPSP amplitude (n = 8). D, LFS-induced LTD was blocked by the application of 50 µM D-AP-5 (n = 4). Insets in A and C represent the first three sweeps of the induction paradigm of a representative experiment. Horizontal bars indicate the presence of the MCPG and D-AP-5, respectively.

A standard protocol for the induction of LTD is the application of prolonged LFS of presynaptic neurons (e.g., 900 pulsesat 1 Hz; Dudek and Bear, 1992). Using this protocol we could onlyinduce long-term depression if the postsynaptic cell was slightlydepolarized to $-$ 62 mV, but not at the resting membrane potentialof $-$ 68 to $-$ 70 mV. As this potential was closer to firing thresholdwe used smaller initial EPSP amplitudes (range, 1-4 mV at $-$ 70mV) to avoid postsynaptic spiking during LFS induction (Fig. 3C,inset). The LFS protocol induced a depression of the EPSPs to40.9 ± 2.5% of the control amplitude (n = 8; p < 0.001; Fig. 3C).Application of D-AP-5 (50 µM) inhibited the induction of LFS-inducedLTD (EPSP amplitude was 100.7 ± 10.4% after 15 min, n = 4; p >0.5, Fig. 3D). Thus, LFS induces an NMDAR-dependent LTD, consistentwith previous reports (Dudek and Bear, 1992; Oliet et al., 1997).In addition, the voltage dependence of the LFS-induced NMDAR LTDwas similar to that described previously (Debanne et al., 1996;Goda and Stevens, 1996; Oliet et al., 1997; Fitzsimonds et al.,1997). In conclusion, associative pairing selectively inducesmGluR-dependent LTD, whereas low-frequency stimulation leads toNMDAR-dependentLTD.

Associative LTD is dependent on activation of voltage-gated Ca²⁺ channels

Previous studies showed that the induction of both mGluR- and NMDAR-dependent LTD is blocked by the Ca²⁺ chelator BAPTA (Mulkey and Malenka, 1992; Oliet et al., 1997).To examine postsynaptic Ca²⁺ signaling in associative LTD, we measured Ca²⁺ transients in the soma and apical dendrites of CA1 pyramidalneurons induced by single backpropagating action potentials using0.1 mM fura-2. After a single action potential, the dendriticCa²⁺ concentration increased by 148 ± 14 nM from a resting value of46 ± 5 nM (distance from soma 40-100 µm; n = 17; Fig. 4A). Thistransient increase in Ca²⁺ concentration decayed to initial baseline levels with a timeconstant of 707 ± 41 msec.

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Figure 4. Associative LTD is dependent on Ca²⁺ influx via both, voltage-gated N- and L-type Ca²⁺ channels. A, Fluorescence image of a CA1 pyramidal neuron filled with 0.1 mM fura-2 (380 nm excitation). Rectangles indicate somatic and dendritic ROIs from where Ca²⁺ transients were recorded with high time resolution (100 Hz, traces on the right). The action potential-induced Ca²⁺ transients were reduced in the presence of 1 µM $omega$ -conotoxin GVIA ( $omega$ -con, N-type blocker). B, The bar graph summarizes the mean inhibition of the Ca²⁺ transient by $omega$ -conotoxin GVIA (n = 6) obtained with 0.1 mM fura-2 and 10 µM nifedipine (n = 5; L-type blocker) obtained with 0.1 mM Oregon Green (see Materials and Methods). Dendritic ROIs were located in the stratum radiatum at a distance of ~0-40 µm or 40-100 µm from the soma. C, Application of 0.5 µM $omega$ -conotoxin GVIA (n = 9) reduced basal synaptic transmission and prevented the induction of LTD by APS. D, A 10 µM concentration of nifedipine did not affect basal transmission but similarly inhibited LTD induction (n = 7). Voltage traces in C and D are EPSPs from a single representative experiment, respectively, at the times indicated by the asterisks.

Application of 1 µM $omega$ -conotoxin GVIA, an irreversible blocker of N-type Ca²⁺ channels, reduced the dendritic Ca²⁺ transients by 38.3 ± 4.6% (n = 6; 40-100 µm; Fig. 4A,B). Thisindicates that N-type Ca²⁺ channels are effectively opened by single backpropagating actionpotentials. To assess the contribution of L-type Ca²⁺ channels, we examined the effects of 10 µM nifedipine. Becausenifedipine is very light-sensitive, we used 0.1 mM Oregon Greeninstead of fura-2 (see Materials and Methods). A single actionpotential evoked a transient fluorescence increase of $Delta$ F/F = 108.5± 13% (n = 14). Application of 10 µM nifedipine reduced the dendriticCa²⁺ transients by 19.4 ± 1.6% (n = 5; 40-100 µm; Fig. 4B). Thus,a single backpropagating action potential induces a reliable Ca²⁺ influx through voltage-gated Ca²⁺ channels in the proximal apical dendrite of CA1 pyramidal neurons,with a substantial amount carried by N- and L-type Ca²⁺channels.

To test the involvement of these channels in LTD induction, we applied the LTD induction protocol in the presence of Ca²⁺ channel antagonists. When 0.5 µM $omega$ -conotoxin GVIA was appliedduring basal synaptic transmission, the EPSP amplitude was reducedfrom 16.8 ± 2.3 mV to 5.8 ± 1.4 mV (n = 9; Fig. 4C), indicatingthe inhibition of presynaptic N-type Ca²⁺ channels that mediate neurotransmitter release (Dunlap et al.,1995). As a higher stimulus intensity was used in these experiments,EPSPs in the presence $omega$ -conotoxin were sufficiently large to examinethe effects of subsequent pairing. Under these conditions theasynchronous pairing protocol failed to induce significant depressionof the EPSP amplitude (102 ± 5.0% of control EPSP amplitude, n= 9; p > 0.5). Although we cannot exclude a contribution of presynapticN-type Ca²⁺ channels, these results suggest that Ca²⁺ influx through postsynaptic N-type channels is required for theinduction of associative LTD. Similarly, we tested the involvementof L-type Ca²⁺ channels in LTD induction (Fig. 4D). In contrast to $omega$ -conotoxin,nifedipine did not reduce the initial EPSP amplitude. However,nifedipine markedly reduced the amount of LTD (reduction of EPSPamplitude to 89.6 ± 4.3%, n = 7; p > 0.5). Thus, postsynapticCa²⁺ influx through voltage-gated Ca²⁺ channels is necessary for the induction of associativeLTD.

Modulation of postsynaptic N-type Ca²⁺ channels inhibits associative LTD

OH-DPAT, a selective agonist of 5-hydroxytryptamine (5-HT)_1A receptors, is known to inhibit N-type Ca²⁺ channels in cortical pyramidal neurons by activation of a G_i/o-protein(Foehring, 1996). Immunocytochemical analysis revealed a highdensity of 5-HT_1A receptors in the hippocampal CA1 region andfurther suggested an exclusively postsynaptic location (Kia etal., 1996). Thus, we considered OH-DPAT as a selective inhibitorof postsynaptic N-type Ca²⁺ channels. As a first experimental step, we examined the effectof OH-DPAT on the action potential-induced Ca²⁺ transient (Fig. 5A). Application of 1 µM OH-DPAT reduced thedendritic Ca²⁺ transients by 25.6 ± 2.7% (n = 5; 40-100 µm). This is consistentwith the previously reported reduction of burst-induced Ca²⁺ transients by 10 µM 5-HT in CA1 pyramidal neurons (Sandler andRoss, 1999).

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Figure 5. Selective suppression of N-type Ca²⁺ channels by 5-HT_1A receptors. A, Action potential-induced Ca²⁺ transients recorded from the CA1 pyramidal neuron shown on the left (0.1 mM fura-2), in control conditions, and in the presence of the 5-HT_1A receptor agonist OH-DPAT (1 µM). B, Whole-cell voltage-clamp recordings from CA1 pyramidal neurons. Modulation of Ca²⁺ channels was analyzed using 30 msec voltage steps from a holding potential of $-$ 90 to $-$ 10 mV and Ba²⁺ as a charge carrier in the bath. The traces show currents in control and after application of 1 µM OH-DPAT (left traces) or OH-DPAT in the presence of 0.5 µM $omega$ -conotoxin GVIA (right traces), respectively. The bar graph summarizes the mean of n = 8 (OH-DPAT), n = 4 ( $omega$ -conotoxin plus OH-DPAT), and n = 4 (nifedipine plus OH-DPAT) experiments. C, Double recording from the soma and the apical dendrite of a CA1 pyramidal neuron (distance between recording sites was 192 µm; inset). Somatic current injection (900 pA, 5 msec) evoked backpropagating action potentials, which did not significantly change after application of 1 µM OH-DPAT. D, The amplitude of the dendritic action potential is plotted against time (top panel, 6 double recordings, normalized to initial value). The average distance was 110 ± 22 µm. The bar graph (bottom panel) summarizes the effect of 1 µM OH-DPAT on somatic and dendritic AP amplitude, on the half width of the dendritic AP and on the propagation velocity relative to control (n = 6).

The reduction in the dendritic Ca²⁺ transient by OH-DPAT could be attributable to a direct inhibition of Ca²⁺ channels or a reduction in the amplitude of the backpropagatingaction potential, or both. For 10 µM 5-HT a slight reduction ofthe amplitude of the backpropagating action potentials was reported(Sandler and Ross, 1999). To distinguish between these possibilities,we blocked Na⁺ and K⁺ channels (see Materials and Methods) and examined Ca²⁺ channels in isolation in the whole-cell voltage-clamp configurationusing 2 mM Ba²⁺ as charge carrier (Fig. 5B). The application of 1 µM OH-DPATreduced the Ba²⁺ currents to 72.9 ± 10.9% (n = 8; p < 0.01). In the presence of $omega$ -conotoxin GVIA the Ba²⁺ currents were reduced to 45.8 ± 6.6% (n = 4). Subsequent to theapplication of $omega$ -conotoxin, the modulation by OH-DPAT was completelyabsent, indicating a selective modulation of N-type Ca²⁺ channels by 5-HT_1A receptors. In the presence of 10 µM nifedipine(84.7 ± 7.0% of control; n = 4), however, there was still a substantialreduction of the Ba²⁺ currents by OH-DPAT (57.0 ± 3.9% of control; p < 0.01).

To examine possible effects of 1 µM OH-DPAT on action potential backpropagation, we made double recordings from the soma andthe apical dendrite of CA1 pyramidal cells at distances of 64-192µm from the soma (Fig. 5C). The shape of the dendritic and somaticaction potential in 1 µM OH-DPAT was very similar to control conditions.The resting membrane potential was slightly hyperpolarized by $-$ 1.0 ± 0.2 mV at the dendrite and by $-$ 0.9 ± 0.2 mV at the soma(p < 0.05; six double recordings). As shown in Figure 5D, theaction potential amplitude in the presence of 1 µM OH-DPAT wasvirtually identical to control conditions (101.2 ± 0.9% of control,n = 6; p > 0.1). Furthermore no significant change in half widthof the dendritic AP (102.1 ± 2.1% of control; p > 0.1) or thepropagation velocity (98.3 ± 3.2% of control; p > 0.1; Fig. 5D)was observed. In conclusion, these results indicate that the reductionof action potential-induced Ca²⁺ transients of 1 µM OH-DPAT is attributable to a direct modulationof postsynaptic N-type Ca²⁺ channels and not to an inhibition of dendriticbackpropagation.

If postsynaptic N-type Ca²⁺ channels are necessary for induction of associative LTD (Fig. 4C) and if these channels are selectivetargets for modulation via 5-HT_1A receptors (Fig. 5), then OH-DPATshould affect LTD induction. We first tested the effect of 1 µMOH-DPAT on basal synaptic transmission, and we found that thepeak EPSP amplitude remained unchanged (Fig. 6A; 95.8 ± 6.4% ofcontrol, n = 11; p > 0.5). This allowed us to use OH-DPAT as atool to inhibit selectively postsynaptic N-type Ca²⁺ channels. In the presence of 1 µM OH-DPAT, application of theasynchronous pairing paradigm failed to induce associative LTD(102.8 ± 4.9% of control, n = 11; p > 0.5; Fig. 6B,C). These resultsindicate that the Ca²⁺ influx via postsynaptic N-type channels is necessary for inductionof associative LTD and that the G-protein-mediated modulationof these channels strongly controls this form of synaptic plasticity.

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Figure 6. Block of associative LTD by inhibition of postsynaptic N-type Ca²⁺ channels via 5-HT_1A receptors. A, The application of 1 µM OH-DPAT did not affect the EPSP amplitude during basal transmission. B, The EPSP amplitude during a single representative experiment is plotted against time. Voltage traces on top are EPSPs from a single representative experiment obtained at the times indicated by the asterisks. C, The mean EPSP amplitude is plotted against time (n = 11). Note that the EPSP amplitude remains constant during application of OH-DPAT. The induction of associative LTD by APS, however, was completely blocked.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Our results show that associative LTD at the Schaffer collateral-CA1 pyramidal cell synapse can be induced reliably by asynchronouspairing of EPSPs with preceding postsynaptic action potentials.The induction was dependent on both mGluRs and postsynaptic voltage-gatedCa²⁺ channels. In particular, we show a direct involvement of N-typeCa²⁺ channels in synaptic plasticity. The modulation of postsynapticN-type Ca²⁺ channels by 5-HT_1A receptors was sufficient to inhibit associativeLTD induced by asynchronouspairing.

Associative LTD is dependent on mGluRs

The induction of LTD by the associative paring protocol was blocked by the mGluR antagonist MCPG, similar to the previouslydescribed mGluR LTD (Bolshakov and Siegelbaum, 1994; Oliet etal., 1997; Otani and Connor, 1998). Although we did not use subtype-specificantagonists, it is likely that the depression is mediated by mGluR5.Immunocytochemical evidence indicates that mGluR5 is the mostabundant metabotropic glutamate receptor present on the postsynapticCA1 pyramidal cells (Shigemoto et al., 1997). Furthermore, thereis evidence for the involvement of the phospholipase C (PLC) signaltransduction pathway in mGluR LTD, consistent with the activationof group 1 mGluRs (Oliet et al., 1997; Otani and Connor, 1998).

The induction mechanism of associative LTD appeared to be different from that of LFS-induced LTD, which was largely blockedby the NMDAR antagonist D-AP-5 (Fig. 3), consistent with previousstudies (Dudek and Bear, 1992; Mulkey and Malenka, 1992). Thecoexistence of two different forms of LTD in hippocampal pyramidalcells was described in detail by Oliet et al. (1997). In bathsolutions containing 2.5 mM Ca²⁺ and 1.3 mM Mg²⁺, LFS primarily induced NMDAR LTD. In 4 mM Ca²⁺ and 4 mM Mg²⁺, however, an additional NMDAR-independent form of LTD was induced,which was dependent on mGluRs and voltage-gated Ca²⁺ channels (Oliet et al., 1997). Because associative LTD in acutehippocampal slices is dependent on mGluRs but not on NMDARs, theasynchronous pairing protocol might be the most physiologicalway to selectively induce the mGluR-dependentLTD.

Thus, two mechanistically distinct forms of LTD coexist in hippocampal pyramidal cells, which can be induced selectively,depending on pyramidal cell firing during network activity (O'Keefeand Reece, 1993). Prolonged presynaptic activity without any postsynapticspiking may decrease the EPSP amplitude via nonassociative LTDdependent on NMDARs, whereas EPSPs that occur repeatedly at acertain time delay with respect to postsynaptic action potentialswill be depressed by associative LTD dependent onmGluRs.

Associative LTD is dependent on activation of postsynaptic Ca²⁺ channels

The mGluR LTD induced by associative pairing could be blocked by the inhibition of either L- or N-type Ca²⁺ channels (Fig. 4). These channels were reliably activated duringsingle backpropagating action potentials (Fig. 4B). This is consistentwith the localization of L- and N-type Ca²⁺ channels on soma and apical dendrites of CA1 pyramidal neurons(Westenbroek et al., 1992; Kavalali et al., 1997; Magee, 1999)and with cell-attached patch recordings from these dendrites (Mageeand Johnston, 1995). In addition, other types of Ca²⁺ channels are expressed in CA1 pyramidal cells, including P-,R-, and T-type channels (Kavalali et al., 1997). They may be responsiblefor the $omega$ -conotoxin- and nifedipine-resistant Ca²⁺-influx.

It may seem surprising that a small (20-40%) reduction of the spatially averaged dendritic Ca²⁺ transient was sufficient to substantially reduce or block theassociative LTD. However, the Ca²⁺ concentration at Ca²⁺-dependent effector molecules may be very different from the measuredCa²⁺ transients. The peak amplitude of the Ca²⁺ transient in submembrane cytoplasmic compartments could be muchhigher because of clustering of Ca²⁺ channels and local saturation of Ca²⁺ buffers (Helmchen et al., 1996). If, for example, N-type Ca²⁺ channels were colocalized with molecules involved in LTD induction,then our data would represent a lower estimate for the contributionof these channels to local Ca²⁺ signals near these effector molecules. Such a colocalizationcould occur in dendritic spines, where action potential-inducedCa²⁺ transients have larger amplitudes than in nearby parent dendrites(Majewska et al., 2000).

Our results and previous reports (Bolshakov and Siegelbaum, 1994; Oliet et al., 1997; Otani and Connor, 1998) converge onthe conclusion that postsynaptic Ca²⁺ influx is essential for LTD induction. However, the target moleculesfor Ca²⁺ remain to be identified. A Ca²⁺-dependent phosphatase is unlikely to be involved, because thephosphatase inhibitor microcystin does not affect mGluR LTD (Olietet al., 1997). An involvement of Ca²⁺-dependent isoforms of PKC is more likely, because PKC inhibitorypeptide blocks mGluR LTD (Oliet et al., 1997; Otani and Connor,1998). Because some PKC isoforms are activated by both diacylglyceroland Ca²⁺ (Nishizuka, 1992), they could operate as molecular coincidencedetectors, onto which the activation of voltage-gated Ca²⁺ channels and group 1 mGluRs converge. This would explain theneed for both postsynaptic action potentials and the release ofglutamate for induction of associativeLTD.

Modulation of N-type Ca²⁺ channels and LTD

The involvement of N-type Ca²⁺ channels in synaptic plasticity is difficult to assess because of the inhibition of basal synaptictransmission by $omega$ -conotoxin GVIA. No selective postsynaptic N-typechannel antagonist is available yet. In our study, the selective5-HT_1A agonist OH-DPAT is a valuable tool to distinguish betweenpresynaptic and postsynaptic N-type channels. A 1 µM concentrationof OH-DPAT, which selectively inhibits postsynaptic N-type channelsby G-protein modulation, was sufficient to block LTD induction.The dependence of associative LTD on N-type Ca²⁺ channels might be important, because N-type Ca²⁺ channels are preferential targets of neuromodulation by variousneurotransmitters like GABA, glutamate, serotonin, somatostatin,and adenosine (Hille, 1994; Kavalali et al., 1997; Magee, 1999).In contrast to the other Ca²⁺ channel types, which provide a more constant basal Ca²⁺ load per action potential, the Ca²⁺ influx through N-type channels is highly regulated. Consequently,the recruitment of N-type channels may determine whether the postsynapticCa²⁺ signal is below or above the threshold for LTDinduction.

The G-protein-mediated modulation of the N-type channels will therefore enable or disable an activity-dependent depressionin synaptic strength. This direct gain control of LTD might berelevant for learning, because learning should occur dependenton behavioral context, which could be signaled by the releaseof differentneuromodulators.

Modulation of associative LTD by backpropagating action potentials

We have shown that N-type Ca²⁺ channels are direct targets of neuromodulation via G-proteins. However, the activation of N-typechannels could be also regulated indirectly by modulation of actionpotential backpropagation. A 1 µM concentration of OH-DPAT, whichis thought to activate selectively 5-HT_1A receptors, did not affectthe properties of the backpropagated spike within the first 200µm of the apical dendrite. In contrast, higher concentrations(30 µM) of OH-DPAT and 5-HT induce a marked hyperpolarizationof CA1 pyramidal cells by 5 and 14 mV, respectively (Andrade andNicoll, 1987), which slightly decrease the amplitude of the backpropagatedspike (Sandler and Ross, 1999). Furthermore, activation of muscarinicand adrenergic receptors regulates dendritic excitability viamodulation of fast dendritic Na⁺ and K⁺ channels (Johnston et al., 1999).

Both the amplitude of the backpropagated spike and the evoked dendritic Ca²⁺ transients decrease with distance from the pyramidal cell soma(Spruston et al., 1995; Magee and Johnston, 1997). Thus, in stratumlacunosum moleculare we would not expect any associative LTD atall, unless backpropagation of action potentials will be enhancedby activation of muscarinic or adrenergic receptors. This willlead to different learning rules for distal and proximal synapses.In general, action potential backpropagation can be very differentin different types of neurons (for review, see Magee, 1999). BothCA1 and neocortical pyramidal neurons show decremental spike backpropagation(Magee and Johnston, 1997; Markram et al., 1997). Hippocampaloriens-alveus interneurons and olfactory bulb mitral cells, however,show nondecremental backpropagation of action potentials intothe dendrites (Bischofberger and Jonas, 1997; Martina et al.,2000). It would be interesting to know whether glutamatergic synapseson these neurons show LTD, and if so, whether LTD has associativeproperties over the entire dendritictree.

Physiological significance of associative LTD

Both associative LTD and LTP in the hippocampus may be important for the dynamical shaping of new place fields during spatiallearning and theta-phase associated pyramidal cell firing (O'Keefeand Reece, 1993; Wilson and McNaughton, 1993). In particular,they may contribute to the learning of temporal sequences in thehippocampus (Skaggs and McNaughton, 1996; Mehta et al., 1997).Whereas associative LTP will strengthen the synapses that precedesubsequent spike discharge of the postsynaptic cell (Magee andJohnston, 1997), associative LTD will depress EPSPs that occurtoo late with respect to the postsynaptic spiking, thus leadingto temporally asymmetric learning rules. Such rules appeared alsoto be very effective for the formation of neuronal cell assembliesin artificial neural networks (Sejnowski, 1999), which was shownto be of critical importance for encoding of spatial informationin the hippocampus (Wilson and McNaughton, 1993).

In conclusion, we suggest that the induction of associative LTD is a powerful mechanism to depress out-of-phase synaptic input.Thus, it may be important to have a direct gain control of associativesynaptic depression, provided by the G-protein-mediated modulationof the voltage-gated N-type Ca²⁺channels.

  FOOTNOTES

Received May 15, 2000; revised Aug. 14, 2000; accepted Aug. 31, 2000.

This work was supported by a grant from the Deutsche Forschungsgemeinschaft Bi 642/1-2 and University funds (J.B.) and bythe Vada and Theodore Stanley Foundation (J.W.). We thank Drs.M. Bartos, J. R. P. Geiger, and M. Martina for critically readingthis manuscript and A. Blomenkamp for technicalassistance.
Correspondence should be addressed to Dr. J. Bischofberger, Physiologisches Institut, Universität Freiburg, Hermann-Herder-Strasse7, D-79104 Freiburg, Germany. E-mail: bischof{at}uni-freiburg.de.

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