Differential Effects of Short- and Long-Term Potentiation on Cell Firing in the CA1 Region of the Hippocampus

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The Journal of Neuroscience, January 1, 2003, 23(1):112-121

Differential Effects of Short- and Long-Term Potentiation on Cell Firing in the CA1 Region of the Hippocampus
Carrie P. Marder and Dean V. Buonomano
Departments of Neurobiology and Psychology, and Brain Research Institute, University of California, Los Angeles, Los Angeles, California 90095

  ABSTRACT

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Long-term potentiation (LTP) in the hippocampus enhances the ability of a stimulus to produce cell firing, not only by increasingthe strength of the EPSPs, but also by increasing the efficiencyof the input/output (I/O) function of pyramidal neurons. Thismeans that EPSPs of a given size more easily elicit spikes afterLTP, a process known as EPSP-spike (E-S) potentiation. In contrastto LTP, it is not known whether the synaptic strengthening producedby paired-pulse facilitation (PPF) also results in changes inthe I/O function. We have addressed this question by examiningE-S curves from rat hippocampal area CA1 in response to both PPFand LTP. We describe a novel form of I/O modulation in which PPFproduces E-S depression; that is, the E-S curve is shifted tothe right, indicating a decreased ability of EPSPs to elicit actionpotentials. Consistent with the notion that E-S potentiation observedwith LTP is caused by long-term increases in the excitatory-inhibitoryratio, we show that PPF-induced E-S depression relies on short-termdecreases in this ratio. These results indicate that differentforms of synaptic plasticity that produce the same degree of EPSPpotentiation can result in dramatically different effects on cellfiring, because of the dynamic changes in the excitatory-inhibitorybalance within localcircuits.

Key words: hippocampus; CA1; inhibition; EPSP-spike potentiation; long-term potentiation; paired-pulse facilitation; input/output; circuit

  Introduction

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

An understanding of how neural networks process information requires insights into the mechanisms whereby synaptic inputstranslate into firing patterns. Whether a neuron fires in responseto a stimulus depends not only on the strength of the excitatorysynapses, but also on intrinsic cellular properties and the netbalance between excitation and inhibition. It is therefore importantto understand how plasticity affects the state of the networkas a whole during short-term forms of synaptic plasticity suchas paired-pulse facilitation (PPF), as well as long-term formsofplasticity.

Long-term potentiation (LTP) is a long-lasting enhancement in synaptic efficacy regarded as the neural basis for learningand memory. LTP can be observed extracellularly as an increasein the size of the field EPSP (fEPSP), as well as an increasein the size and decrease in the latency of the population spike(Bliss and Gardner-Medwin, 1973; Bliss and Lomo, 1973). The extracellularlyrecorded population spike reflects the number of synchronouslyfiring cells (Andersen et al., 1971). The relationship betweenthe fEPSP and the population spike can thus be used to characterizethe input/output (I/O) function of CA1 pyramidal neurons (Andersenet al., 1980). The first LTP studies noted that the potentiationof the population spike was often greater than could be accountedfor by the fEPSP potentiation alone, and that in some cases, populationspike potentiation occurred in the absence of fEPSP potentiation(Bliss and Gardner-Medwin, 1973; Bliss and Lomo, 1973). This phenomenonwas later termed EPSP-spike (E-S) potentiation (Andersen et al.,1980).

In this study, we have asked whether E-S potentiation also accompanies the changes in synaptic efficacy seen on a shortertime scale. The functional role of short-term plasticity is notwell understood but has been theorized previously to contributeto temporal processing on a scale of tens to hundreds of milliseconds(Buonomano and Merzenich, 1995; Buonomano, 2000). Here we haveused a paired-pulse paradigm in the range relevant to temporalinformation processing to produce short-term synaptic facilitationin area CA1. We found that although paired-pulse stimulation strengthensexcitatory synapses, it does not translate into the predictedincrease in action potential firing. In contrast to the E-S potentiationthat accompanies LTP, E-S depression accompanies PPF at shortinterpulse intervals (IPIs) (50-100 msec). We propose that PPFleads to E-S depression through a relative increase in inhibition,and, in agreement with previous studies, that LTP is paralleledby a relative decrease in inhibition (Abraham et al., 1987; Chavez-Noriegaet al., 1989; Lu et al., 2000). An understanding of these parallelchanges occurring within excitatory-inhibitory disynaptic circuitswill be fundamental to elucidating the functional effects of bothshort- and long-term EPSPplasticity.

  Materials and Methods

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Slice preparation. Experiments were performed on 400-µm-thick transverse hippocampal slices from 17- to 28-d-old Sprague Dawleyrats. The hippocampus was dissected out after halothane anesthesiaand decapitation. Slices were cut from the dorsal hippocampuswith a vibratome and submerged in oxygenated artificial CSF (ACSF)at room temperature. The ACSF was composed of (in mM): 119 NaCl,2.5 KCl, 1.3 MgSO₄, 1.0 NaH₂PO₄, 26.2 NaHCO₃, 2.5 CaCl₂, and 10glucose. For picrotoxin experiments, the CA3 region was removedwith a knife cut. After an equilibration period of at least 1hr, slices were transferred to a submerged recording chamber perfusedat a rate of 2.5-3 ml/min and maintained at a temperature of 32± 1°C.

Field recordings. Microelectrodes were pulled from borosilicate glass [1.5 mm outer diameter (O.D.)/1.17 mm inner diameter(I.D.)] using a Flaming/Brown electrode puller (Sutter Instruments,Novato, CA). Two microelectrodes filled with 1 M NaCl (1-5 M $Omega$ )were placed extracellularly in area CA1 to simultaneously recordpopulation spikes from stratum pyramidale and fEPSPs from stratumradiatum (see Fig. 1A). The microelectrodes were advanced to approximatelythe same depth in the slice and positioned along a line perpendicularto the cell bodylayer.

Sharp intracellular recordings. In some experiments, an intracellular micropipette was used in place of the population spikeelectrode. Because we hypothesized that the excitation-inhibitionbalance is of importance and because whole-cell recordings canconsiderably alter the IPSP reversal potential, we used sharprecordings. Micropipettes were pulled from borosilicate glass(1.2 mm O.D./0.68 mm I.D.) using a Flaming/Brown electrode puller(Sutter Instruments). Their resistance when filled with 3 M potassiumacetate varied from 60 to 100 M $Omega$ . Cell penetrations were consideredacceptable if they met the following criteria: resting potentialbelow $-$ 60 mV, input resistance of $>=$ 30 M $Omega$ , and overshooting actionpotentials. Spike latency was calculated as the time from thestimulus artifact to the action potential peak. Hyperpolarizationwas calculated as the difference in base voltage 2-5 msec beforea first stimulus and 2-5 msec before a second stimulus arriving50 msec later (see Fig. 9B).

Electrical stimulation. For stimulation, platinum-iridium bipolar electrodes coated with platinum black (Frederick Haer Co.,Bowdoinham, ME) were placed in stratum radiatum, at the CA3-CA1border and at the subicular end of CA1. The distance between therecording and stimulating sites was between 250 and 450 µm. Biphasic,constant current, 100 µsec stimuli were delivered in pairs alternatelyto the two stratum radiatum inputs at 10-12 sec intervals. Typically,paired pulses were given 50 msec apart. In the first set of experiments,a cycle of five interpulse intervals was used (50, 100, 200, 300,and 400 msec). Baseline intensity was set below the thresholdfor population spikes, and stable baseline recordings were obtainedfor 10-20 min before basal E-S curves weremeasured.

For LTP experiments, baseline recordings were reestablished for ~5 min after completion of the basal E-S curves. LTP was inducedin one pathway by high-frequency stimulation (100 Hz for 1 sec,repeated two times at an interval of 20 sec), during which timethe second pathway remained unstimulated. E-S curves were acquiredat 13 min and again at 30 min aftertetanus.

Pharmacology. For drug experiments, 100 µM picrotoxin (PTX) or 15 µM flurazepam (FLZ) was dissolved in ACSF and bath appliedafter completion of the basal E-S curves. At least two additionalE-S curves were then obtained in the presence of the drug. Ina separate set of experiments (see Fig. 7A), the effects of FLZwere examined intracellularly on pharmacologically isolated evokedIPSPs. IPSPs were isolated by including 50 µM APV and 10 µM CNQX(dissolved in 1 ml DMSO) in the ACSF. After successful cell penetrationand a period of stable baseline recording, FLZ (15 µM) was addedto the APV/CNQX solution, and recordings were continued for anadditional 30 min. All drugs were acquired from Sigma (St. Louis,MO).

E-S curves. To obtain the data for the E-S curves, an ascending-descending series of ~20-30 stimulation intensities (50-500µA) was applied multiple times, covering a range of responsesfrom subthreshold to supramaximal. E-S curves were constructedby plotting population spike amplitude versus fEPSP slope overthe entire range of intensities sampled. The fEPSP slope was calculatedas the absolute value of the maximal slope of the descending phasebetween 5 and 95% of the negative peak response. Population spikeamplitude was calculated as the difference between the averageof the two peak positivities and the peak negativity. Becausethe E-S curve for the second pulse reaches its upper asymptoteat a lower intensity than the first pulse, in some experimentspaired-pulse stimulation was switched to single pulse stimulationat the highest intensities. Only those experiments having stablebaselines and stable E-S curves over multiple trials were includedin theanalysis.

Curve fitting was done using a custom-written MATLAB program. The program provided the best fit using a sigmoid with threefree parameters: S = S_max/(1 + exp [(E₅₀ $-$ E)/k]), where S_maxis the asymptote, E₅₀ is the fEPSP slope at 1/2 S_max, and k reflectsthe slope of the sigmoid. To ensure that any differences in thecurve fits were not caused by the range of values sampled, curvesfor pulse 2 were fit using only the data points falling below5-10% of the maximum y-value obtained for pulse 1. The extra pointsare indicated in the E-S plots by smallermarkers.

Intracellular E-S curves. Intracellular E-S curves resemble the conventional E-S curves except that the output measure (y-axis)was derived from the action potential firing probability of asingle cell. Spikes were detected from sharp intracellular recordingsas peak amplitudes exceeding a threshold value. Spike probabilitywas calculated as the percentage of trials eliciting spikes ata given intensity. Thus, to plot the intracellular E-S curve,each stimulation setting of the I/O curve was applied for 10 consecutivesweeps. The x-value plotted was the average fEPSP slope over those10 trials; the y-value plotted was the number of spikes. Notethat the fEPSP at the threshold level of stimulation, definedas the intensity that produces five spikes in 10 trials, is thesame as the E₅₀ of the intracellular E-Scurve.

Statistics. For statistical comparisons of E-S curves, we analyzed the percentage change in E₅₀, a standard measure, plustwo new measures: horizontal shift and vertical shift. These weredefined as the percentage change from the control curve E₅₀ tothe horizontal and vertical intersections with the second curve(see Fig. 1C). Horizontal shift resembles E₅₀ shift but is a morereliable and conservative measure when comparing two E-S curvesthat have different upper asymptotes. For the intracellular E-Scurves, the upper asymptote is fixed at 100% cell firing probability(10 spikes/10 trials), so the standard E₅₀ shift was used in thesecases. Note that the E₅₀ shift is equal to the horizontal shiftfor intracellular E-S curves. Statistical analyses of the shiftswere done using two-tailed, one-sample t tests to determine significantdifferences from zero. Two-tailed paired t tests were used forthe flurazepamdata.

  Results

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Paired-pulse facilitation produces E-S depression

We recorded simultaneous extracellular responses in stratum radiatum (fEPSPs) and stratum pyramidale (population spikes) fromarea CA1 of rat hippocampal slices while delivering paired stimuliover a series of intervals and intensities. A schematic diagramof the electrode arrangement is shown (Fig. 1A). The fEPSP slopeprovides a measure of the excitatory drive to the CA1 pyramidalneurons; the population spike amplitude reflects the number ofpyramidal neurons producing action potentials. Both the fEPSPsand population spikes were facilitated at the 50 msec IPI (Fig.1A), with smaller degrees of facilitation visible at longer intervals(Fig. 1B). We compared the E-S curves generated by the two pulsesat five IPIs by cycling through five IPIs at each intensity settingand plotting the resulting fEPSP-spike pairs (Fig. 1C,D).

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Figure 1. Field EPSPs produced by paired-pulse facilitation elicit less firing than single fEPSPs of the same size: E-S depression. A, Schematic diagram of stimulating and recording electrode positions in CA1, with sample Schaffer collateral-evoked extracellular responses to paired pulses with 50 msec IPI. FEPSPs (top traces) were recorded from stratum radiatum (S. Rad.), the dendritic layer, and population spikes (bottom traces) were recorded from stratum pyramidale (S. Pyr.), the cell body layer. Gray lines indicate slope and amplitude measurements. B, Overlay of five consecutive sweeps of paired pulses at five IPIs using the same intensity. Both fEPSPs (top row) and population spikes (bottom row) showed PPF at all IPIs tested: 50, 100, 200, 300, and 400 msec. Dotted outline indicates the traces shown in A. C, E-S curves for the 50 msec data from the experiment shown above. E-S curves were plotted for pulse 1 (open circles, gray line) and pulse 2 (filled circles, black line) as the population spike amplitude versus fEPSP slope over a range of intensities. A larger marker indicates the calculated E₅₀ for each curve. $Delta$ x and $Delta$ y are additional values used for the quantification of E-S shifts, calculated as the distances from the E₅₀ of the first curve to the horizontal ( $Delta$ x) and vertical ( $Delta$ y) intersections with the second curve. At the 50 msec IPI, the E-S curve was shifted to the right, as reflected by positive values of $Delta$ x and $Delta$ E₅₀, and negative $Delta$ y. The sample voltage traces show that when matched for fEPSP slope (top row), pulse 2 (black traces) generated a smaller population spike (bottom row) than pulse 1 (gray traces). Traces correspond to the fEPSP slope indicated by the vertical dotted line. D, E-S curves for the 100, 200, 300, and 400 msec IPIs.

At the 50 msec IPI (Fig. 1C), the E-S curve for pulse two was shifted to the right. This implies that the second pulse requireda larger fEPSP to generate a population spike of a given size.Similarly, for a given fEPSP size, the second pulse generateda smaller population spike. In keeping with the established terminology,we refer to this rightward shift of the E-S curve as "E-S depression"(Andersen et al., 1980). The sample voltage traces (Fig. 1C) demonstratethat when matched for fEPSP slope, the second pulse produced lessfiring than the first. Thus, although both fEPSPs and populationspikes were facilitated with a 50 msec IPI, there was less firingin response to the second pulse than would have been expectedfor the increased synaptic drive. By 400 msec, the E-S curvesfor the two pulses coincided, as would independent, single pulses(Fig. 1D).

The summary statistics (Fig. 2) show that the E-S curve was significantly shifted rightward at 50 msec (t₁₃ = 3.9; p < 0.005)and at 100 msec (t₁₃ = 3.1; p < 0.01) and not at the longer intervals.We used three methods to quantify the E-S shifts (see Materialsand Methods), and each yielded a similar result.

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Figure 2. PPF shifts the E-S curve rightward at 50 and 100 msec. Quantification of E-S shifts from 14 experiments was done using three measures (Fig. 1C). A, The percentage change $Delta$ x/x (horizontal shift), where x is the E₅₀ of the E-S curve of the first pulse. B, The percentage change in E₅₀ from pulse 1 to pulse 2, or [E₅₀(2) $-$ E₅₀(1)]/E₅₀(1). C, The percentage change $Delta$ y/y (vertical shift), where y is the y-value at E₅₀ of the E-S curve of the first pulse. Each measure revealed a significant rightward shift at 50 and 100 msec. Bars represent the mean shift; error bars represent SEM. Asterisks indicate a value significantly different from zero (*p < 0.05; **p < 0.01).

Differential effects of PPF and LTP on cell firing

We next compared the E-S shifts produced by PPF with those produced by LTP in the same slices. We used paired-pulse stimulationwith a 50 msec IPI and induced LTP by tetanic stimulation. Thetime course of a typical experiment is shown in Figure 3A. Notethat the degree of PPF of the fEPSP slope before the tetanus isequal to the degree of LTP of the fEPSP slope measured 30 minafter the tetanus. Thus, one might have expected each of thesefEPSPs to produce a similar amplitude population spike. The recordingsfrom the cell body layer, however, show that only LTP produceda measurable population spike at this intensity (Fig. 3A, redtraces) and that the same increase in synaptic strength producedby PPF did not result in cell firing (Fig. 3A, black traces).

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Figure 3. PPF and LTP produce opposite effects on EPSP-spike coupling. A, Time course of normalized fEPSP slopes for pulse 1 ( $open circle$ ) and pulse 2 () from a typical LTP experiment. Data were normalized to the baseline pulse 1 value, at time a, 5 min before LTP induction. Brackets indicate durations used for collecting I/O data for the E-S curves. Note that the stimulus intensity was systematically changed in an ascending-descending manner. Paired-pulse stimulation was applied throughout with 50 msec IPI, and LTP was induced by high-frequency tetanization (100 Hz, 1 sec × 2) at time 0. Note that the magnitude of PPF before the tetanus at time a equals the magnitude of LTP 25-30 min after the tetanus at time b. Sample voltage traces are the average of 10 consecutive responses, for pulse 1 (gray) and pulse 2 (black) at time a, and for the first pulse 30 min after the tetanus at time b (red). Note that PPF and LTP produced the same enhancement of synaptic strength (fEPSP, top traces), but only LTP resulted in action potential firing at this intensity (population spike, bottom traces). Arrow points to the small population spike produced at this intensity after LTP. B, E-S curves of the data shown in A before and after tetanization. E-S curves were plotted for pulse 1 (open circles, gray line) and pulse 2 (filled circles, black line) before LTP, and for pulse 1 (red triangles, red line) after LTP. PPF and LTP shifted the E-S curve in opposite directions. Arrows indicate horizontal shifts. Sample voltage traces from all three conditions are shown. The fEPSP slopes were matched by plotting the data points corresponding to the vertical dotted line near 3 mV/msec. For the same-sized fEPSP slope (top traces), LTP (red) resulted in a larger population spike (bottom traces), and PPF (black) resulted in a smaller population spike, compared with the basal (gray) population spike produced by increasing the intensity alone.

By plotting the E-S curves using a range of intensities, we saw a differential effect of PPF and LTP on the entire I/O function(Fig. 3B). PPF shifted the E-S curve rightward, indicating E-Sdepression (t₁₃ = 12; p < 0.001), whereas LTP shifted the E-Scurve leftward, indicating E-S potentiation (t₁₃ = $-$ 3.3; p < 0.01)(for summary statistics, see Fig. 4). The traces in Figure 3Bfurther illustrate that inputs of the same synaptic strength cangenerate different outputs. The fEPSPs produced by LTP resultedin more firing, and the fEPSPs produced by PPF resulted in lessfiring, compared with fEPSPs of the same size produced under basalconditions.

To test whether E-S potentiation is pathway specific (Andersen et al., 1980; Abraham et al., 1985; Wathey et al., 1992; Jesteret al., 1995), we performed experiments using a control, untetanizedpathway (summary data) (Fig. 4). We found no significant shiftof the basal E-S curve in the control pathway (t₅ = 1.4; p > 0.2)measured before and after tetanization of the experimental path.This shows that E-S potentiation is pathway specific and indicatesthat for the unpotentiated inputs, the E-S curve is stable overthe course of a typical experiment. We also examined whether theE-S depression produced by PPF was altered by LTP (summary data)(Fig. 4). After LTP, PPF continued to shift the E-S curve to theright (t₁₃ = 5.6; p < 0.001), and the E-S depression was not significantlydifferent before and after LTP (t₁₃ = $-$ 1.0; p > 0.3).

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Figure 4. Summary of E-S shifts for PPF and LTP. Group data in which the E-S curves for PPF and LTP were measured in the same experiments. PPF shifted the E-S curve rightward (p < 0.001; n = 14), whereas LTP shifted the E-S curve leftward (p < 0.01; n = 14). After LTP, PPF continued to shift the E-S curve rightward (p < 0.001; n = 14). In a control, untetanized pathway, there was no significant shift of the E-S curve (p > 0.2; n = 6) measured before and after tetanization of the other pathway. Open triangles indicate the LTP experiments using a control pathway. Asterisk indicates a significant difference from zero (p < 0.01). N.S., Not significant.

To test whether E-S depression is pathway specific, we performed experiments using two pathways. Pathway one (P1) was heldat a fixed intensity, whereas pathway two (P2) was varied overa range of intensities as described above (see Materials and Methods).Paired pulses 50 msec apart were delivered homosynaptically (P2-P2)and heterosynaptically (P1-P2) in alternation, and the responsesin P2 were analyzed for E-S shifts (Fig. 5A). We found significantE-S depression in P2 as a result of both homosynaptic (p < 0.005;t₄ = 7.57) and heterosynaptic (p < 0.001; t₄ = 9.2) stimulation(Fig. 5B). This shows that E-S depression is not pathway specific.

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Figure 5. E-S depression is not pathway specific. A, E-S curves from a sample experiment in which paired stimuli 50 msec apart were delivered homosynaptically (P2-P2) and heterosynaptically (P1-P2). The E-S curves shown correspond to responses in P2 as follows: Pulse 1, open circles, gray line; Pulse 2, black filled circles, black line; the heterosynaptic pulse (P2 preceded by P1), gray filled circles, gray dashed line. Note that both homosynaptic and heterosynaptic stimulation shifted the E-S curve rightward. B, Summary data from five experiments; individual experiments are indicated by filled circles. There is a significant mean rightward shift of the E-S curve in both the homosynaptic and heterosynaptic conditions (bars represent the mean; error bars represent SEM; *p < 0.005).

Blocking GABA_A receptors blocks PPF-induced E-S depression

The E-S depression that we observed during PPF could rely, in principle, on the inhibitory branch of the local circuit (Fig.6D) or on a cellular mechanism such as spike accommodation ora slow afterhyperpolarization. Furthermore, an inhibitory rolecould operate via GABA_A receptor (GABA_AR)-mediated fast IPSPsor GABA_BR-mediated presynaptic or postsynaptic mechanisms. Asalready shown (Fig. 2), the maximum E-S shifts occurred with the50-100 msec IPIs, and no detectable shifts occurred with the 200-300msec IPIs. Because it is well established that presynaptic andpostsynaptic GABA_BR effects peak at 200-300 msec (Fukuda et al.,1993; Buonomano and Merzenich, 1998), it is unlikely that GABA_BR-mediatedmechanisms are contributing to E-S depression. We therefore usedPTX, a GABA_AR antagonist, to test the hypothesis that E-S depressionrelies on network mechanisms.

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Figure 6. Picrotoxin blocks PPF-induced E-S depression. A, Sample voltage traces in control conditions (ACSF, left) and picrotoxin (PTX, 100 µM, right). Gray traces are pulse 1 fEPSP (top row) and population spike (bottom row); black traces correspond to pulse 2 (50 msec IPI), matched to the same fEPSP slope as pulse 1 (see vertical dotted lines in B). Note the E-S depression of pulse 2 in ACSF but not in PTX. B, E-S curves obtained for the experiment shown in A. Before PTX, PPF shifted the E-S curve to the right (gray line to black line). Consistent with the circuits shown in D, PTX itself produced a dramatic shift in the E-S curve leftward (gray line to gray dashed line) and prevented any further rightward shift by PPF (gray dashed line to black dashed line). C, Average data from four experiments shows that the PPF-induced right shift requires intact inhibition. In normal ACSF, PPF shifted the E-S curve to the right. In PTX, PPF shifted the E-S curve to the left. Bars represent the mean; error bars represent SEM; asterisks indicate a significant difference from zero (*p < 0.05; **p < 0.01). D, Schematic diagram of disynaptic circuit composed of an excitatory and inhibitory neuron arranged in a feedforward manner. The circuit is composed of three different synapses: Input $right-arrow$ Ex (Schaffer collateral to pyramidal neuron), Input $right-arrow$ Inh (Schaffer collateral to inhibitory interneuron), and Inh $right-arrow$ Ex (inhibitory to pyramidal neuron). A relative increase in inhibition would shift the E-S curve rightward, whereas a relative decrease in inhibition would shift the E-S curve leftward.

We repeated the above experiments while blocking the GABA_ARs with 100 µM PTX (Fig. 6A). To maximize the E-S depression inthe control condition, we used a 50 msec IPI. We first obtainedE-S curves in the absence and then in the presence of PTX (Fig.6B) (in these experiments, the CA3 region was removed; see Materialsand Methods). In agreement with previous studies of E-S potentiation,bath application of the GABA_AR antagonist itself caused a largeleftward shift of the E-S curve (Abraham et al., 1987; Chavez-Noriegaet al., 1989; Lu et al., 2000). Nevertheless, although in fourof four experiments PPF elicited the usual rightward shift beforeapplication of PTX (t₃ = 6.2; p < 0.01), no rightward shifts occurredin the presence of PTX. In fact, PTX appears to have reversedthe effect of PPF on the E-S curve from a rightward to a leftwardshift (t₃ = $-$ 5.7; p < 0.05) (Fig. 6C). This implies that intrinsicconductances are not responsible for the rightward shift, andindeed that intrinsic membrane properties may favor E-S potentiationrather than E-Sdepression.

These experiments suggest that GABA_AR-mediated inhibition is necessary for PPF-induced E-S depression to occur. However, becausePTX itself produced a significant shift of the first pulse E-Scurve, the absence of a rightward shift could be caused, in part,by differences in initial conditions. To address this issue, wenext examined the role of GABA_AR-mediated inhibition by usinga benzodiazepineagonist.

Benzodiazepine enhances PPF-induced E-S depression without shifting the basal E-S curve

The experiments above suggest that GABA_Aergic processes contribute to the E-S depression accompanying PPF. One possibilityis that inhibition produced by the first pulse counteracts theEPSP facilitation at the second pulse. This hypothesis predictsthat increasing the duration of the first IPSP should furtherenhance the magnitude of the right shift observed during PPF.To test this hypothesis we used a benzodiazepine agonist, whichenhances the duration of fast IPSPs onto pyramidal neurons (Modyet al., 1994) (Fig. 7A). Although we have focused on the benzodiazepineeffects on pyramidal cells, it should be noted that similar effectsmight occur on inhibitory neurons (Hajos et al., 2000; Patenaudeet al., 2001).

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Figure 7. Benzodiazepine enhances PPF-induced E-S depression. A, Sample intracellular recording of pharmacologically isolated IPSPs (10 µM CNQX and 50 µM APV) before (black trace) and after (gray trace) addition of 15 µM flurazepam (FLZ). Traces are the average of 20 sweeps. Vertical line is drawn to indicate the mean action potential latency of pulse 1 (5.1 msec) recorded in pyramidal cells under intact pharmacological conditions in a separate set of experiments (Figs. 8, 9). Note that the enhancement of the IPSP by FLZ primarily changes the later phases of the IPSP relative to the spike latency for pulse 1. B, Sample field recordings from another slice in normal ACSF (black traces) and after addition of 15 µM FLZ (gray traces). Top row, fEPSPs; bottom row, population spikes. FLZ did not change baseline fEPSP slope or PPF of the fEPSP slope; however, the second fEPSP elicited less firing (a smaller population spike) in the presence of FLZ. C, E-S curves from the experiment displayed in B. FLZ produced no change in the basal E-S curve, Pulse 1 (open circles, gray line), compared with FLZ, Pulse 1 (open triangles, gray dashed line); however, PPF in FLZ resulted in a larger rightward shift (gray arrow) than in ACSF (black arrow). D, Summary data of horizontal shifts produced by PPF in normal ACSF and in FLZ in the same experiments. The mean difference (Diff.) indicates a significantly greater rightward shift in FLZ compared with normal ACSF (p < 0.005; n = 14). No change was found in the Pulse 1 E-S curve before and after FLZ (p > 0.25; n = 14). Bars represent the mean; error bars represent SEM; asterisk represents a significant difference from zero (p < 0.005).

FLZ (15 µM) did not change the baseline slope of the first fEPSP or the degree of PPF (Fig. 7B) (Tuff et al., 1983). Subtlechanges in fEPSP waveform shape were observed, such as a narrowershape consistent with enhancement of the IPSP. In the presenceof FLZ, although PPF was the same, the second pulse elicited lessfiring (a smaller population spike) than was observed previouslyin normal ACSF (Fig. 7B) (Tuff et al., 1983). This diminishedfiring on the second pulse accounts for the significant increasein the rightward shift of the E-S curve seen after addition ofFLZ (Fig. 7C,D) (t₁₃ = 3.9; p < 0.005). Note that in contrastto PTX (Fig. 6B), FLZ did not shift the Pulse 1 E-S curve (Fig.7C,D) (t₁₃ = 1.09; p = 0.29). Because FLZ enhanced the rightwardshift but did not alter the E-S curve of the first pulse, theseresults indicate that GABA_Aergic processes play a role in PPF-inducedE-S depression. Specifically, these data support the hypothesisthat E-S depression depends on the strength of the firstIPSP.

PPF-induced E-S depression in single pyramidal neurons

To confirm that PPF-induced E-S depression is observed at the single-cell level, and to further examine the underlying mechanisms,we performed intracellular experiments with sharp electrodes.We constructed intracellular E-S curves using action potentialfiring probability in place of population spike amplitude (seeMaterials and Methods). In general, compared with conventionalE-S curves, the upper asymptotes of intracellular E-S curves (definedas 10 spikes/10 trials) were reached using less intense stimulationand smaller fEPSPs. Figure 8 shows a representative intracellularexample of PPF-induced E-S depression. Some cells, on the otherhand, exhibited E-S potentiation (Fig. 9A). As with the fieldE-S curves, there was a mean rightward shift (Fig. 9A) (t₄₉ =3.19; p < 0.005) of ~13.2%, approximately the same percentageshift as determined previously using field recordings (Figs. 2,4).

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Figure 8. Intracellular demonstration of E-S depression. A, Sample voltage traces from a representative experiment near threshold. Top row, fEPSPs; average of 10 consecutive responses to paired stimuli (50 msec IPI) at 260 µA (black) and then at 300 µA (gray). Bottom row, The corresponding 10 intracellular recordings at the two intensities, showing both spike-free and spike-containing EPSP-IPSP sequences. Note that the first intensity produced 3 of 10 spikes on pulse 2, and the second intensity produced 3 of 10 spikes on pulse 1, but the corresponding fEPSPs show that pulse 2 required a larger fEPSP to reach the same spike probability. B, Intracellular E-S curves for pulse 1 (open circles, gray line) and pulse 2 (filled circles, black line) from the same experiment shown in A. Note that the pulse 2 E-S curve is shifted to the right (arrow indicates E₅₀ shift). The dotted line passes through the points corresponding to the threshold traces shown in A. The intracellular traces at threshold are redrawn to the right superimposed, to show that the second pulse reaches threshold on a larger EPSP that originates from a more hyperpolarized potential.

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Figure 9. Intracellular E-S depression correlates with inhibition. A, Summary of intracellular E-S shifts. Open circles represent E₅₀ shift in 50 experiments (28 cells). Bar represents the mean; error bars represent ±SEM. There was a mean rightward shift of the E-S curve; asterisk indicates a significant difference from zero (p < 0.005). B, Traces at threshold for pulse 2 (same cell as Fig. 8A). Arrow indicates hyperpolarization from base (dotted line). C, Significant correlation (r = $-$ 0.43; p < 0.005) between E₅₀ shifts in single cells and the magnitude of hyperpolarization preceding the second pulse.

To confirm that E-S depression is caused by inhibition, we analyzed two additional measures that reflected IPSP strength:the hyperpolarization from resting potential at 45-48 msec aftera stimulus (just before pulse 2) (Fig. 9B) and the EPSP decaytime constant ( $tau$ _D) (data not shown). To quantify these measuresfor each experiment, we averaged over the 10 sweeps closest tothreshold intensity for pulse 2 (Fig. 9B). We found that the magnitudeof E-S depression in single cells significantly correlated withthe magnitude of the hyperpolarization (Fig. 9C) (r = $-$ 0.43; t₄₈= $-$ 3.31; p < 0.005) as well as (inversely) with the $tau$ _D of thefirst EPSP (r = $-$ 0.42; t₄₈ = $-$ 3.24; p < 0.005). This supportsthe conclusion that E-S depression results from inhibition ofcell firing on the second facilitated EPSP, because of the influenceof the firstIPSP.

  Discussion

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

E-S coupling provides a measure of the I/O function of a population of cells. It is well known that LTP can enhance the I/Ofunction of pyramidal neurons through the process of E-S potentiation(Andersen et al., 1980; Abraham et al., 1987; Chavez-Noriega etal., 1989; Leung and Au, 1994; Lu et al., 2000). The intracellularcorrelate of E-S potentiation, a decreased EPSP slope at actionpotential firing threshold, has also been established after LTP(Andersen et al., 1980; Abraham et al., 1987). In addition, ithas been reported that short-term potentiation induced by high-frequencystimulation does not produce a change in the E-S curve (Abrahamet al., 1985). Similarly, a previous study examining paired pulsesalso reported no shift or a leftward shift (Leung and Fu, 1994).However, both of these studies relied on somatic field responsesonly, and thus could not provide an accurate measure of the I/Ofunction, because EPSPs recorded in the cell layer are maskedby a strong feedforward inhibitory component (Pouille and Scanziani,2001). Here we show for the first time that PPF, which can producethe same degree of fEPSP potentiation as LTP, produces a consistentdepression of the pyramidal cell I/O function. This E-S depressionmanifests at the both the population and single-celllevels.

The PPF-induced E-S depression observed here is to some extent similar to paired-pulse suppression of population spikes describedin vivo in the dentate gyrus (Tuff et al., 1983). There are notabledistinctions, however. A triphasic pattern is seen in the dentategyrus, with depression of population spikes at short (20-30 msec)and long (150-500 msec) IPIs, presumably mediated by GABAergicinhibition, and facilitation at intermediate IPIs (50-90 msec)(Tuff et al., 1983; Burdette and Gilbert, 1995). More importantly,it has been shown that the early depression of population spikesis predicted by depression of the fEPSP slopes (Burdette and Gilbert,1995, their Fig. 2B). In contrast, we have shown a reliable facilitationof fEPSPs and population spikes, with simultaneous EPSP-spikedepression.

Mechanism of PPF-induced EPSP-spike depression

E-S depression could rely on cellular or network mechanisms. The rightward shift in E-S depression signifies that in comparisonto the first pulse, the second pulse requires a larger EPSP toproduce an action potential. On the cellular side, this E-S depressioncould result from decreased excitability of the cell, as a consequenceof the afterhyperpolarization, for example. On the network side,E-S depression could rely on relative changes in the balance ofexcitation and inhibition. The PTX experiments (Fig. 6) implystrongly that normal PPF-induced E-S depression relies on intactinhibitory pathways using GABA_ARs. There are two major sourcesof inhibition of CA1 pyramidal neurons: feedforward and feedback(Buzsaki, 1984; Freund and Buzsaki, 1996). Although both are likelyto contribute to E-S depression, feedforward inhibition is morelikely to play a principal role. This is because feedback inhibitionrelies on the firing of the pyramidal neurons (Buzsaki, 1984),and E-S curves for pulse 2 were usually generated at intensitiesbelow population spike threshold for pulse 1. Furthermore, singlecells were found to reach threshold for pulse 2 without firingon pulse 1 (Fig. 9B). Alternatively, feedforward inhibition isactivated by these low, subthreshold stimulation intensities (Buzsaki,1984; Karnup and Stelzer, 1999) and is likely to be the majorcontributor to the E-S depression observedhere.

E-S depression could occur as a result of PPF in the disynaptic inhibitory branch of the circuit (Fig. 6D) or temporal overlapof the EPSP of the second pulse with the residual fast IPSP ofthe first pulse (Fig. 9B). Because it is believed that paired-pulsedepression (PPD) predominates at the inhibitory-to-excitatory(Inh $right-arrow$ Ex) synapses in the hippocampus (Davies et al., 1990; Yoonand Rothman, 1991; Mott et al., 1993), the first explanation seemsunlikely. We have confirmed in our experiments on pharmacologicallyisolated IPSPs that paired-pulse stimulation with a 50 msec IPIproduces marked PPD of the monosynaptic IPSP (data not shown).Evidence from paired recordings, however, suggests that both PPFand PPD can occur at the Inh $right-arrow$ Ex synapses, as well as at pyramidalcell inputs onto interneurons (Ali and Thomson, 1998; Ali et al.,1998; Jiang et al., 2000; Maccaferri et al., 2000). It thereforeremains uncertain whether paired-pulse modulation in the disynapticpathway could produce a net increase in inhibition evoked on thesecond pulse, but this is unlikely, given the strong evidencefor PPD ofIPSPs.

We have used the benzodiazepine agonist FLZ to test the possibility that PPF causes E-S depression by temporal overlap ofthe second EPSP with the residual fast IPSP. As a class, benzodiazepinesenhance the frequency of bursting of GABA_AR-mediated Cl channels (MacDonald and Meldrum, 1989), resulting in prolongedGABAergic currents and extended IPSPs (Otis and Mody, 1992; Modyet al., 1994) (Fig. 7A). The temporal summation explanation forE-S depression predicts that enhancement of the residual IPSPby FLZ could profoundly affect action potential firing on thesecond pulse without affecting firing on the first pulse. Indeed,as shown in Figure 7, FLZ significantly increased the rightwardshift in response to PPF, without significantly shifting the basalE-S curve. These data, along with the intracellular data showinga correlation between E-S depression and the hyperpolarizationpreceding the second stimulus (Fig. 9C), strongly support thehypothesis that the temporal overlap of the second EPSP with thefirst IPSP causes E-Sdepression.

Supportive evidence is also provided by the data showing that E-S depression is not pathway specific (Fig. 5). Note that althoughthe IPSP hypothesis predicts a heterosynaptic effect, it doesnot predict whether the magnitude of the effect should be completeor partial. This is because (1) there is no a priori way to equatethe degree of inhibition activated by each pathway, and (2) thestimulation intensity used for pathway one was fixed, whereasthe stimulation intensity for pathway two was varied. Therefore,the magnitude of the shift in the heterosynaptic case will notbe comparable with the magnitude of the shift in the homosynapticcase. Although these data are potentially confounded, becauseit is difficult to exclude the possibility of overlap betweenthe pathways at high intensities, the results suggest that E-Sdepression is heterosynaptic, consistent with the IPSPhypothesis.

Mechanism of LTP-induced EPSP-spike potentiation

E-S potentiation produced by LTP could be caused by long-term changes in cell excitability (Haas and Rose, 1982; Abraham etal., 1985; Taube and Schwartzkroin, 1988; Wathey et al., 1992;Jester et al., 1995) or by increases in the ratio of excitationto inhibition (Wilson et al., 1981; Abraham et al., 1987; Chavez-Noriegaet al., 1989; Lu et al., 2000). Andersen et al. (1980) arguedthat E-S potentiation could not be explained by increased intrinsicexcitability of pyramidal cells, because an untetanized controlpath failed to elicit the effect. A relative loss of inhibitionresulting from greater LTP onto pyramidal cells (Input $right-arrow$ Ex) comparedwith interneurons (Input $right-arrow$ Inh) has been proposed as a mechanismfor E-S potentiation (Wilson et al., 1981; Abraham et al., 1987).Additionally, a molecular mechanism has been described involvingLTD of the GABA_AR-mediated IPSP that occurs in parallel with LTPof the EPSP and requires activation of NMDA receptors and calcineurin(Lu et al., 2000). Consistent with either of these mechanismsis the finding that E-S potentiation is blocked by GABA_AR antagonistssuch as PTX or bicuculline (Abraham et al., 1987; Chavez-Noriegaet al., 1989; Lu et al., 2000).

A fundamental issue is whether the protocol that induces LTP of the Input $right-arrow$ Ex synapses in CA1 also produces long-term plasticityof the Input $right-arrow$ Inh or Inh $right-arrow$ Ex synapses. E-S potentiation could beproduced by concomitant LTD of either of these synapses. Tetanus-inducedInput $right-arrow$ Inh LTP (Stelzer et al., 1994; Cowan et al., 1998) and LTD(McMahon and Kauer, 1997) have been observed. Similarly, bothLTP (Xie et al., 1995) and LTD (Lu et al., 2000) have been reportedat the Inh $right-arrow$ Ex synapses. This variability may reflect differencesin the inhibitory cell types being examined. For instance, inCA1, stratum oriens interneurons undergo LTP, either directly(Perez et al., 2001) or propagated passively from potentiatedpyramidal neurons (Ouardouz and Lacaille, 1995; Maccaferri andMcBain, 1996), whereas stratum radiatum interneurons undergo direct,tetanus-induced LTD (McMahon and Kauer, 1997).

Although our studies did not set out to examine the mechanisms underlying LTP-induced E-S potentiation, our results showingthat E-S potentiation is pathway specific are consistent withchanges in inhibition (Abraham et al., 1987; Chavez-Noriega etal., 1989; Lu et al., 2000).

Computational implications

Changes in synaptic strength produced by short-term or long-term plasticity play an important role in neural computation.The computational consequences of LTP have long been thought tounderlie learning and memory. Specifically, increases in synapticstrength translate into increases in neuronal firing, which inturn may facilitate the generation of a particular behavior. Asdiscussed above, neuronal firing depends not only on the strengthof EPSPs, but also on the net balance between excitation and inhibition(Buzsaki, 1984; Pouille and Scanziani, 2001). Although LTP ofEPSPs has not generally been studied in the context of parallelchanges in inhibition, previous results (Bliss and Gardner-Medwin,1973; Bliss and Lomo, 1973; Andersen et al., 1980; Abraham etal., 1987; Kairiss et al., 1987; Chavez-Noriega et al., 1989;Lu et al., 2000) and the data shown here indicate that LTP doestranslate into increased cell firing. It remains to be shown,however, whether the shift in E-S coupling during LTP occurs underphysiological induction of LTP, such as pairing-induced associativeLTP in single pyramidalcells.

The computational role of short-term forms of plasticity such as PPF and PPD has been less clear. PPF has been proposed tobe involved in temporal processing (Buonomano and Merzenich, 1995;Buonomano, 2000) and "on-line" modulation of neural circuits (Fisheret al., 1997). PPD has been proposed to contribute to synchronygeneration (Tsodyks et al., 2000) and gain control (Abbott etal., 1997), maintaining the stability of cortical circuits bykeeping positive feedback in check (Galarreta and Hestrin, 1998).We have suggested previously that PPF coupled with dynamic changesin excitatory-inhibitory balance in disynaptic circuits can leadto the generation of interval selective neurons (Buonomano, 2000).We define a disynaptic circuit as being composed of a single projectingexcitatory and local inhibitory neuron arranged in a feedforwardmanner (Fig. 6D). Within this circuit there are three differentsynapses that can potentially undergo plasticity: Input $right-arrow$ Ex, Input $right-arrow$ Inh,and Inh $right-arrow$ Ex. Theoretical work has shown that parallel plasticityat two of these synapses can be used to tune neurons to differentintervals (Buonomano, 2000). These previous data, together withthe results presented here, emphasize that the full computationalpotential of neural circuits may rely on parallel modulation ofdifferent synaptic loci, rather than short- and long-term plasticityof the Input $right-arrow$ Ex synapsealone.

Although we have focused on paired-pulse plasticity, we speculate that with longer trains of stimuli, there may be dynamicchanges in the E-S shifts. One possibility is that PPD of theIPSPs would eventually offset the E-S depression produced by temporaloverlap of a given EPSP with the preceding IPSP. Depending onchanges in the relative balance of excitation and inhibition,attributable to PPF of the EPSPs, PPD of the IPSPs, and long-lastinginhibition, the E-S curve might start out shifted rightward fordouble pulses and move steadily leftward for later pulses in thetrain. This would act to amplify the output of later EPSPs whileminimizing the output of earlierEPSPs.

Conclusion

Our results provide an example of how the same excitatory synaptic strengths can translate into different outputs. This occursas a result of the dynamic balance between excitation and inhibition.Specifically, in the system studied here, inhibition can counteractshort-term facilitation of excitatory synapses. Thus, to understandthe functional effects of both short- and long-term synaptic plasticity,it is necessary to determine the net effect of parallel changesoccurring at multiple synapticloci.

  FOOTNOTES

Received July 23, 2002; revised Sept. 26, 2002; accepted Oct. 7, 2002.

This research was supported by the EJLB Foundations, the National Science Foundation, and the National Institutes of Health(NIH). C.P.M. was supported by the NIH National Institute of GeneralMedical Sciences training Grant GM08042, the Medical ScientistTraining Program, the Aesculapians Fund of the University of CaliforniaLos Angeles School of Medicine, and the Achievement Rewards forCollege Scientists Foundation. We thank Holly Carlisle, Uma Karmarkar,Victor Marder, Tom O'Dell, and David Stanton for reading earlierversions of thismanuscript.

Correspondence should be addressed to Dean V. Buonomano, Brain Research Institute, University of California, Los Angeles,Box 951761, Los Angeles, CA 90095. E-mail: dbuono{at}ucla.edu.

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