Postsynaptic Complex Spike Bursting Enables the Induction of LTP by Theta Frequency Synaptic Stimulation

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The Journal of Neuroscience, September 15, 1998, 18(18):7118-7126

Postsynaptic Complex Spike Bursting Enables the Induction of LTP by Theta Frequency Synaptic Stimulation
Mark J. Thomas¹, Ayako M. Watabe², Teena D. Moody¹, Michael Makhinson¹, and Thomas J. O'Dell²
¹ Interdepartmental PhD Program for Neuroscience and ² Department of Physiology, School of Medicine, University of California, Los Angeles, Los Angeles, California 90095

  ABSTRACT

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Long-term potentiation (LTP), a persistent enhancement of synaptic transmission that may be involved in some forms of learningand memory, is induced at excitatory synapses in the CA1 regionof the hippocampus by coincident presynaptic and postsynapticactivity. Although action potentials back-propagating into dendritesof hippocampal pyramidal cells provide sufficient postsynapticactivity to induce LTP under some in vitro conditions, it is notknown whether LTP can be induced by patterns of postsynaptic actionpotential firing that occur in these cells in vivo. Here we reportthat a characteristic in vivo pattern of action potential generationin CA1 pyramidal cells known as the complex spike burst enablesthe induction of LTP during theta frequency synaptic stimulationin the CA1 region of hippocampal slices maintained in vitro. Ourresults suggest that complex spike bursting may have an importantrole in synaptic processes involved in learning and memory formation,perhaps by producing a highly sensitive postsynaptic state duringwhich even low frequencies of presynaptic activity can induceLTP.

Key words: long-term potentiation; complex spike burst; hippocampus; pyramidal cells; synaptic transmission; learning and memory

  INTRODUCTION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

At many excitatory synapses, coincident activity in the presynaptic terminal and postsynaptic cell induces long-term potentiation(LTP), a persistent enhancement of synaptic transmission thoughtto have a role in certain forms of learning and memory (Blissand Collingridge, 1993). The significance of coincident presynapticand postsynaptic activity in the induction of LTP lies in thefact that it provides the simultaneous release of glutamate andpostsynaptic membrane depolarization necessary for activationof NMDA-type glutamate receptors. Calcium influx through NMDAreceptor ion channels in turn triggers a complex, protein kinase-dependentsignaling pathway ultimately responsible for the modificationsthat enhance synaptic transmission (Bliss and Collingridge, 1993).

Until recently, the strong postsynaptic depolarization required for NMDA receptor activation and LTP induction was thoughtto arise primarily from the temporal and spatial summation ofEPSPs during high-frequency stimulation of multiple presynapticfibers (Nicoll et al., 1988; Gustafsson and Wigström, 1990; Debanneet al., 1996). However, recent findings showing that action potentialsinitiated near the cell body back-propagate into pyramidal celldendrites (Magee and Johnston, 1995; Spruston et al., 1995) suggestthat dendritic action potentials may provide an additional meansof achieving the postsynaptic depolarization needed to activateNMDA receptors and induce LTP. Indeed, EPSPs paired with back-propagatingdendritic action potentials can induce LTP under some in vitroconditions (Scharfman and Sarvey, 1985; Magee and Johnston, 1997;Markram et al., 1997). Although these findings suggest that dendriticaction potentials may have an important role in the inductionof LTP, it is not yet known whether patterns of action potentialfiring observed in CA1 pyramidal cells in vivo are sufficientand/or necessary for LTP induction.

In vivo, hippocampal CA1 pyramidal cells generate action potentials either as single, isolated spikes or in high-frequencybursts of two or more action potentials that progressively declinein amplitude and increase in duration during the burst (Kandeland Spencer, 1961; Ranck, 1973; Fox and Ranck, 1975; Suzuki andSmith, 1985). This second mode of firing, known as the complexspike burst, is a defining electrophysiological signature of hippocampalpyramidal cells (Ranck, 1973; Fox and Ranck, 1975) and may representan important form of information coding in the hippocampus (Lisman,1997). Complex spike bursts may also have an important role inhippocampal synaptic plasticity because patterns of presynapticfiber stimulation that mimic complex spike bursting can, undercertain conditions, induce LTP (Larson et al., 1986; Huerta andLisman, 1993, 1995; Hölscher et al., 1997). Because action potentialsduring complex spike bursts back-propagate into CA1 pyramidalcell dendrites in vivo (Buzáki et al., 1996), complex spike burstsmight also have an important postsynaptic role in the inductionof LTP by providing the postsynaptic activity needed for NMDAreceptor activation. Thus, to determine whether EPSPs paired withpatterns of postsynaptic spiking that occur in CA1 pyramidal cellsin vivo can induce LTP, we investigated the postsynaptic roleof both single action potentials and complex spike bursts in theinduction of LTP during theta frequency synaptic stimulation.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Transverse hippocampal slices, 400 µm thick, were obtained from halothane-anesthetized male mice (C57BL/6) using standardtechniques. Unless noted otherwise, all experiments were doneusing animals between 4 and 7 weeks of age. None of our findingsvaried with animal age. Although 5 Hz synaptic stimulation caninduce long-term depression in slices from very young animals(Bolshakov and Siegelbaum, 1994; Oliet et al., 1997), it doesnot induce LTD in the CA1 region of hippocampal slices obtainedfrom mice in the age range used in our experiments (Mayford etal., 1995; Thomas et al., 1996). Slices were maintained in aninterface recording chamber (Fine Science Tools, Inc.) and perfusedwith an artificial mouse CSF (ACSF) consisting of (in mM): 124NaCl, 4.4 KCl, 25 NaHCO₃, 1 NaH₂PO₄, 1.2 MgSO₄, 2 CaCl₂, and 10glucose (gassed with 95% O₂ and 5% CO₂; temperature, 30°C). Schaffercollateral and commissural fibers were stimulated at 0.02 Hz witha bipolar nichrome wire stimulating electrode (0.02 msec durationpulses), and EPSPs evoked in CA1 pyramidal cells were recordedextracellularly in stratum radiatum with an ACSF-filled glassmicroelectrode (5-10 M $Omega$ ). Glass microelectrodes (60-120 M $Omega$ ) filledwith 3 M K-acetate or 2 M K-methylsulfate were used in intracellularrecordings. Only cells with resting membrane potentials more negativethan $-$ 55 mV and with overshooting action potential amplitudeswere used. Stimulation intensity was adjusted to evoke field EPSPs(fEPSPs) that were 50% of the maximal fEPSP amplitude (strongintensity stimulation) or 20-25% of the maximal response (weakintensity stimulation). In two pathway experiments, independenceof the fibers activated by two stimulating electrodes was confirmedby the lack of paired-pulse facilitation when one pathway wasstimulated 50 msec after the other. CA1 pyramidal cells were antidromicallyactivated using a stimulating electrode placed in the alveus andstimulation intensities sufficient to evoke near-maximal antidromicpopulation spikes (recorded with an extracellular electrode instratum radiatum). Slices showing any evidence of contaminationof the antidromic response by activation of fibers in stratumoriens were not used.

All stimulation protocols as well as data acquisition and analysis were performed using Experimenter's Workbench (Data WaveTechnologies Inc.). Negative-going spikes appearing in fEPSP recordingswere manually counted off-line by visually inspecting each tracerecorded during 5 Hz stimulation. This analysis was done in ablind manner. All values are reported as mean ± SEM, and Student'st tests were used to assess statistical significance.

Salts used in the ACSF were purchased from Sigma (St. Louis, MO). All other compounds were purchased from Research Biochemicals(Natick, MA). Concentrated stock solutions of nifedipine and nimodipine(in dimethylsulfoxide) were prepared fresh daily under dim light,and experiments were done in the dark to minimize light exposure.

  RESULTS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Five hertz synaptic stimulation induces postsynaptic complex spike bursting

Although complex spike bursting is a characteristic mode of action potential firing in vivo (Kandel and Spencer, 1961; Ranck,1973; Fox and Ranck, 1975), relatively few CA1 pyramidal cellsin the in vitro hippocampal slice preparation generate complexspike-like bursts of action potentials when depolarized by currentinjected through an intracellular microelectrode (Jensen et al.,1996). The paucity of cells that generate complex spike burstsunder physiological conditions in vitro thus hinders an analysisof how this mode of action potential firing may be involved inthe induction of LTP. However, as has been observed in vivo (Suzukiand Smith, 1988), we observed that CA1 pyramidal cells in thein vitro hippocampal slice preparation fire complex spike-likebursts of action potentials during trains of synaptic stimulationdelivered at 5 Hz, a stimulation frequency that corresponds tothe hippocampal theta rhythm that occurs in vivo (Bland, 1990).As shown in Figure 1A, during 5 Hz stimulation negative-goingspikes superimposed on the fEPSPs appeared after ~40-50 stimulationpulses and gradually grew in number and amplitude. Intracellularrecordings from individual CA1 pyramidal cells (n = 9) confirmedthat the spikes seen in the extracellular recordings were attributableto bursts of action potentials in the postsynaptic CA1 pyramidalcells (Fig. 1B). Moreover, we found that bursting during 5 Hzstimulation was prevented in CA1 pyramidal cells impaled withmicroelectrodes containing the Na⁺ channel blocker QX-314 (100 mM; n = 7; Fig. 1B), indicating thatthe bursts are generated postsynaptically in a voltage-sensitiveNa⁺ channel-dependent manner. The interspike intervals (5-7 msec),progressive decrease in spike amplitude, and progressive increasein spike duration during these 5 Hz stimulation-induced burstsare characteristic electrophysiological features of complex spikebursts recorded in vivo (Kandel and Spencer, 1961; Ranck, 1973;Fox and Ranck, 1975).

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Figure 1. Complex spike bursting in CA1 pyramidal cells is induced by 5 Hz stimulation. A, The histogram shows the mean number of spikes evoked by each stimulation pulse during 30 sec of 5 Hz stimulation (n = 22). On average, complex spike-like bursting (number of spikes > 1) does not begin until the 40th pulse of 5 Hz stimulation. The line indicates the mean + 1 SEM. The traces, right, show fEPSPs recorded in stratum radiatum at the indicated time points during a 30-sec-long train of 5 Hz stimulation. Note the negative (downward) spikes that appear in the last two evoked responses. Calibration: 2 mV, 10 msec. B, Examples of simultaneously recorded field (top) and intracellular (bottom) responses during 5 Hz stimulation. Note that in control recordings (left) the negative-going spikes present in the extracellular recording correspond to action potentials in the intracellular recording. Although strong bursting is evident in the extracellular recording, no bursting occurs in the cell impaled with a QX-314-containing microelectrode (right). Calibration: 2 mV, 5 msec (extracellular traces); 15 mV, 5 msec (intracellular traces). C, The histograms show the percentage of EPSPs (mean ± SEM) that evoke at least one action potential (left) or a complex spike burst (right) during 150 pulses of 5 Hz stimulation in the absence (open bars; n = 9 cells) or presence of 250 nM TTX (filled bars; n = 9 cells). In the absence of TTX, the time course of EPSP-evoked complex spike bursting recorded intracellularly was similar to that determined from extracellular recordings as shown in A.

In agreement with previous reports indicating that a highly TTX-sensitive, persistent Na⁺ conductance has a crucial role in burst generation in CA1 pyramidalcells (Azouz et al., 1996; Jensen et al., 1996), we found thata brief (10 min) application of TTX (250 nM) had little effecton excitatory synaptic transmission (see below) or on the generationof single action potentials but produced a near-complete suppressionof complex spike bursting (Fig. 1C). During intracellular recordingsfrom CA1 pyramidal cells we observed that when 150 pulses of 5Hz stimulation were delivered in the absence of TTX, EPSPs elicitedcomplex spike bursting (defined as two or more action potentialswith interspike intervals of <10 msec) on 61 ± 6% of stimulationpulses (n = 9 cells). In contrast, although EPSPs reliably evokedsingle action potentials during 150 pulses of 5 Hz stimulationin the presence of 250 nM TTX (10 min application), complex spikebursts were observed on only 3 ± 2% of the stimulation pulses(n = 9 cells).

Five hertz synaptic stimulation induces an associative, NMDA receptor-dependent form of LTP

If complex spike bursts provide a sufficient level of dendritic depolarization to relieve the voltage-dependent Mg²⁺ ion block of the NMDA receptor, then the EPSP-evoked bursts thatoccur during 5 Hz stimulation should induce LTP. As shown in Figure2A, 30 sec of 5 Hz stimulation induced a persistent potentiationof synaptic transmission that was significantly reduced when 5Hz stimulation was delivered in the presence of the NMDA receptorblocker 2-amino-5-phosphonovaleric acid (100 µM DL-APV). As isthe case for certain high-frequency stimulation protocols (Groverand Teyler, 1990; Johnston et al., 1992; Ito et al., 1995), 5Hz stimulation appears to induce LTP through both NMDA receptor-dependentand -independent signaling pathways because a small, but significant(p < 0.01), potentiation was still evident 45 min after 5 Hz stimulationin APV. In experiments in which we doubled the effective concentrationof APV by using 100 µM D-APV a similar APV-resistant potentiationwas also induced (fEPSPs were potentiated to 117.8 ± 2.5% of baseline45 min after 5 Hz stimulation; n = 4), suggesting that the residualpotentiation induced in the presence of APV is not attributableto incomplete NMDA receptor blockade. NMDA receptor-independentLTP of excitatory synaptic transmission in the CA1 region of thehippocampus is thought to be caused by Ca²⁺ influx through voltage-sensitive Ca²⁺ channels, because inhibitors of L-type (Grover and Teyler, 1990)or T-type (Ito et al., 1995, Magee and Johnston, 1997) Ca²⁺ channels can block this component of high-frequency stimulation-inducedLTP. We found that 5 Hz stimulation-induced LTP was not inhibitedby the L-type Ca²⁺ channel antagonists nifedipine and nimodipine [fEPSPs were potentiatedto 151.4 ± 11.3% of baseline (n = 5) 45 min after 5 Hz stimulationin 10 µM nifedipine and to 153.2 ± 10.2% of baseline (n = 5) after5 Hz stimulation in 20 µM nimodipine]. However, the T-type Ca²⁺ channel blocker Ni²⁺ significantly reduced the amount of potentiation induced by 5Hz stimulation [fEPSPs were 123.6 ± 4.4% of baseline 45 min after5 Hz stimulation in 50 µM NiCl₂ (n = 8) compared with 153.7 ±7.7% of baseline in paired control experiments (n = 8); t₍₁₄₎= 3.38; p < 0.005]. In the presence of both 50 µM NiCl₂ and 100µM DL-APV, fEPSPs were 107.5 ± 2.7% of baseline 45 min after 5Hz stimulation (n = 8) compared with 151.1 ± 5.8% of baselinein paired control experiments (n = 6). Thus, activation of bothNMDA receptors and T-type Ca²⁺ channels appears to contribute to the induction of LTP by 5 Hzstimulation. Nifedipine, nimodipine, Ni²⁺, and APV did not block 5 Hz stimulation-induced complex spikebursting, suggesting that activation of L-type and T-type Ca²⁺ channels as well as NMDA receptors is not required for complexspike bursting.

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Figure 2. Complex spike bursts enable LTP induction during 5 Hz stimulation. A, A 30 sec train of 5 Hz stimulation was delivered (at time = 0). In control experiments (filled symbols) fEPSPs were potentiated to 148.6 ± 5.3% of baseline (n = 27) 45 min after 5 Hz stimulation, whereas fEPSPs were 117.3 ± 4.8% of baseline after 5 Hz stimulation in 100 µM DL-APV (open symbols; n = 7; significantly less than control, p < 0.01). B, Weak-intensity stimulation of a single pathway (open symbols; n = 9) failed to induce a persistent change in synaptic transmission. In contrast, LTP was induced when a pathway activated with weak-intensity stimulation (filled symbols; n = 5) was coactivated during 5 Hz stimulation with an independent pathway stimulated at a high intensity. For clarity the results from activation of the strong pathway are not shown (EPSPs in the pathway activated by strong-intensity 5 Hz stimulation were potentiated to 166.7 ± 11.0% of baseline; n = 5). C, A 10 min bath application of 250 nM TTX (indicated by the bar) blocks the induction of LTP by 5 Hz stimulation. Forty-five minutes after 5 Hz stimulation in TTX (filled circles), fEPSPs were 102.4 ± 4.2% of baseline (n = 7), whereas synaptic transmission was potentiated to 147.3 ± 8.5% of baseline in control experiments (no TTX; open circles; n = 10). Bath application of TTX alone had no effect on synaptic transmission (diamonds; n = 5). Traces are fEPSPs recorded at the end of 5 Hz stimulation in control and TTX experiments. Calibration: 2 mV, 10 msec. D, TTX does not inhibit the induction of LTP by two trains of 100 Hz stimulation (1 sec duration; intertrain interval = 10 sec, delivered at time = 0). fEPSPs were potentiated to 187.0 ± 12.8% of baseline 60 min after tetanus in control experiments (open symbols; n = 7) and were potentiated to 188.3 ± 9.1% of baseline after 100 Hz stimulation in 250 nM TTX (indicated by the bar, filled symbols; n = 7).

We further characterized the potentiation induced by 5 Hz stimulation by investigating the effects of presynaptic fiber stimulationstrength on the induction of LTP. Although strong-intensity 5Hz stimulation induced LTP, weak-intensity stimulation failedto induce both complex spike bursting and LTP (Fig. 2B). LTP couldbe induced in a group of synapses activated by weak-intensitypresynaptic stimulation, however, if these synapses were coactivatedduring 5 Hz stimulation with a strongly stimulated independentgroup of synaptic inputs that elicited complex spike bursting(Fig. 2B). Thus, like high-frequency stimulation-induced LTP (Nicollet al., 1988, Gustafsson and Wigström, 1990; Bliss and Collingridge,1993), 5 Hz stimulation induces an associative form of LTP wherebyindependent groups of synapses can interact in a positive mannerto induce LTP.

Complex spike bursting is required for the induction of LTP by 5 Hz stimulation

To determine whether complex spike bursts are required for the induction of LTP during 5 Hz stimulation, we examined whetherpharmacologically suppressing complex spike bursting could preventthe induction of LTP by strong-intensity 5 Hz stimulation. BecauseT-type calcium channels appear to be involved in the inductionof LTP by 5 Hz stimulation, we did not attempt to use intracellularelectrodes containing the Na⁺ channel blocker QX-314 in these experiments because this compoundalso inhibits T-type Ca²⁺ channels (Talbot and Sayer, 1996). Instead, because our earlierexperiments confirmed previous findings that low concentrationsof TTX inhibit bursting with little effect on the generation ofsingle action potentials (Azouz et al., 1996), we examined whetherLTP induction was blocked when complex spike bursting during 5Hz stimulation was suppressed by TTX. Although a short applicationof 250 nM TTX had no effect on baseline synaptic transmission,it strongly suppressed complex spike bursting during 5 Hz stimulationand blocked the induction of LTP (Fig. 2C). In contrast, 250 nMTTX had no effect on high-frequency stimulation-induced LTP (Fig.2D). Thus, TTX does not have generalized effects on synaptic transmissionthat prevent the induction of LTP, suggesting that the TTX blockof 5 Hz stimulation-induced LTP is caused by the suppression ofcomplex spike bursting. Moreover, because these concentrationsof TTX have little effect on the ability of EPSPs to evoke singlepostsynaptic action potentials (Fig. 1C), the TTX block of 5 Hzstimulation-induced LTP suggests that bursts, rather than singleaction potentials, are specifically required for LTP induction.

We also examined the need for complex spike bursting in 5 Hz stimulation-induced LTP by determining whether LTP could be inducedby pairing EPSPs with antidromically stimulated bursts of actionpotentials that mimicked complex spike bursting (three actionspotentials at 200 Hz, beginning 7 msec after the start of theEPSP; Fig. 3A, inset). Although strong-intensity 5 Hz trains thatterminated before complex spike bursting began (5 Hz for 5 sec)induced little persistent change in synaptic strength, significantLTP was induced when this short train of 5 Hz stimulation waspaired with antidromic stimulation that mimicked complex spikebursting (Fig. 3A). Antidromic stimulation alone had no effecton synaptic transmission (n = 3; data not shown). It has beenreported (Jester et al., 1995) that pairing antidromic actionpotentials with orthodromic synaptic stimulation fails to induceLTP in the CA1 region of the hippocampus. There are numerous methodologicaldifferences between our experiments and those described in thisreport, especially with respect to the patterns and numbers ofantidromic and orthodromic stimulation pulses used during pairing.Although we have not investigated which of these variables accountfor these different results, we believe it is significant thatin our experiments LTP was induced by stimulation protocols specificallydesigned to mimic EPSP-evoked complex spike bursting. We alsoobserved that LTP could be induced by pairing complex spike-likeantidromic stimulation with another low-frequency synaptic stimulationprotocol (50 pulses at 2.5 Hz) that alone failed to induce complexspike bursting and had no lasting effect on synaptic transmission(Fig. 3B). In these experiments fEPSPs were 105.6% of baseline45 min after 2.5 Hz synaptic stimulation alone (n = 8) and 149.5± 10.2% of baseline after pairing 2.5 Hz synaptic stimulationwith antidromic bursts (n = 9). Consistent with the results fromour experiments with TTX that suggest that EPSPs paired with singlepostsynaptic action potentials are not sufficient for LTP induction,a single pulse of antidromic stimulation paired with 2.5 Hz synapticstimulation (delivered 7 msec after the EPSP) failed to induceLTP (Fig. 3B).

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Figure 3. A, Twenty-five pulses of 5 Hz synaptic stimulation alone has little persistent effect on synaptic transmission (open symbols; fEPSPs were 109.7 ± 2.8% of baseline 45 min after 5 Hz stimulation; n = 22) but induces LTP when paired with complex spike burst-like antidromic stimulation (filled symbols; fEPSPs were potentiated to 152.9 ± 9.63% of baseline; n = 14; significantly greater than synaptic stimulation alone, p < 0.005). Inset, Response during pairing of synaptic and antidromic burst stimulation (calibration: 5 mV, 5 msec). These experiments were done using slices from animals between 3 and 4 weeks of age (n = 14 for 5 Hz stimulation alone; n = 8 for 5 Hz stimulation paired with antidromic stimulation) and between 5 and 7 weeks of age (n = 8 for 5 Hz stimulation alone; n = 6 for 5 Hz stimulation paired with antidromic stimulation). The results from these two groups of animals were not different and have been combined. B, Complex spike burst-like antidromic stimulation induces LTP when paired with 50 pulses of 2.5 Hz synaptic stimulation (filled circles; n = 9), whereas pairing EPSPs with a single antidromic stimulation pulse has no lasting effect on synaptic strength (open circles; n = 6; EPSPs were 103.2 ± 4.4% of baseline). Fifty pulses of 2.5 Hz stimulation alone had no effect on synaptic strength (filled triangles; n = 8). C, Mean number of spikes in fEPSP recordings evoked by each of 75 pulses of 5 Hz stimulation during the continuous train (right; SEM values ranged from 0 to 0.46) and during five trains of 15 pulses (left; intertrain interval, 7 sec; SEM values ranged from 0 to 0.41). D, Seventy-five pulses of 5 Hz stimulation induced LTP when delivered as a continuous train (open symbols; fEPSPs were potentiated to 142.7 ± 11.9% of baseline; n = 8) but had little effect on synaptic transmission when delivered as five trains of 15 pulses (filled symbols; EPSPs were 110.72 ± 5.2% of baseline; n = 8; significantly less than potentiation induced by continuous 75 pulse train, p < 0.025). Data from the same experiments shown in C.

Finally, because EPSPs evoked complex spike bursts with a characteristic delay after the start of a 5 Hz stimulation train,we also investigated whether delivering 5 Hz stimulation as acontinuous train that elicited complex spike bursting or as severalshort groups of stimulation pulses that were not long enough forcomplex spike bursting to begin could affect the induction ofLTP. We found that although 75 pulses of 5 Hz stimulation deliveredas a continuous train induced complex spike bursting and LTP,75 stimulation pulses delivered as five trains of 15 pulses (intertraininterval, 7 sec) failed to induce complex spike bursting and hadlittle lasting effect on synaptic transmission (Fig. 3C,D).

High levels of complex spike bursting are required for LTP induction during long trains of 5 Hz stimulation

If the induction of LTP by low-frequency synaptic stimulation depends solely on EPSP and complex burst coincidence, then LTPshould be reliably induced by all trains of stimulation that produceat least the minimal or threshold number of coincident EPSP andcomplex spike bursts needed to activate the NMDA receptor-dependentsignaling pathways responsible for LTP. However, when we examinedthe effect of train duration on both complex spike bursting andLTP induction, the results clearly indicated that LTP was notsimply induced after the occurrence of some threshold number ofEPSP-evoked complex spike bursts. As shown in Figure 4A, duringa 3 min long train of 5 Hz stimulation (900 pulses), complex spikebursting was prominent during the first 150 stimulation pulsesand then gradually declined, terminating on average by the 300thstimulation pulse. When we examined the effects of different duration5 Hz trains on the induction of LTP, we observed that when LTPwas induced by 75 and 150 pulse trains of 5 Hz stimulation, shorter(25 pulses) or longer (300 and 900 pulses) trains had little persistenteffect on synaptic strength (Fig. 4B). These results indicatethat short trains of 5 Hz stimulation (25 pulses) that terminatebefore complex spike bursting begins fail to induce LTP and thatby 75 pulses of 5 Hz stimulation a sufficient number of EPSP-evokedcomplex spike bursts (27 ± 5, mean ± SEM) have occurred to induceLTP. Yet, when 5 Hz stimulation was continued for longer periods(300 and 900 pulses) no LTP was induced, even though the totalnumber of EPSP-evoked complex spike bursts was six to nine timesgreater during longer trains of 5 Hz stimulation than during the75 pulse train (Fig. 4B, inset). Thus, although EPSP-evoked complexspike bursting can activate the NMDA receptor-dependent processesrequired for LTP induction, it appears that other cellular processesthat inhibit LTP induction are also activated during longer trainsof 5 Hz stimulation. Indeed, previous studies have shown thatNMDA receptor activation can activate processes that increasethe threshold for LTP induction and/or reverse previously establishedLTP (Fujii et al., 1991; Huang et al., 1992; O'Dell and Kandel,1994). Based on previous observations that protein phosphataseinhibitors enhance the induction of LTP by long, but not short,trains of 5 Hz stimulation (Thomas et al., 1996) and prevent thereversal of previously established LTP by 5 Hz stimulation (O'Delland Kandel, 1994), it seems likely that protein phosphatase activationimportantly contributes to the inhibition of LTP induction duringlong trains of 5 Hz stimulation.

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Figure 4. EPSP-complex spike burst coincidence regulates the induction of LTP. A, Mean number of EPSP-evoked spikes seen in the fEPSP recordings for each stimulation pulse during 3 min of 5 Hz stimulation (n = 10). For clarity, SEM bars, which ranged from 0 to 0.38, are not shown. B, Summary of the amount of LTP induced by various duration trains of 5 Hz stimulation. Each point is the mean (±SEM) amount of potentiation measured 45 min after 5 Hz stimulation. The number of experiments is indicated next to each point. Inset, Absolute number of EPSP-evoked complex spike bursts for each train of 5 Hz stimulation. C, Mean number of spikes seen in fEPSP recordings for each stimulation pulse during six 150-pulse trains of 5 Hz stimulation (intertrain interval, 20 sec; n = 9; SEM values ranged from 0 to 0.43). Note the large increase in the number of EPSPs that evoke bursting during patterned stimulation compared with continuous stimulation (A). D, Nine hundred pulses of 5 Hz stimulation delivered as a single, continuous train (open symbols) fail to induce significant LTP (fEPSPs were 109.63 ± 5.8% of baseline; n = 10). In contrast, fEPSPs were potentiated to 150.3 ± 10.4% of baseline when 900 stimulation pulses were delivered as six trains of 150 pulses (filled symbols; n = 9; p < 0.005 compared with baseline). Data from the same experiments shown in A and C.

Modest levels of NMDA receptor activation during low-frequency synaptic stimulation are thought to activate protein phosphatasesby producing modest increases in intracellular calcium (Mulkeyand Malenka, 1992; Lisman, 1994; Cummings et al., 1996). In contrast,more intense NMDA receptor activation is thought to elicit a largerincrease in intracellular calcium that both activates the proteinkinases directly responsible for inducing LTP (Bliss and Collingridge,1993) and inhibits the activity of protein phosphatases that mightoppose the induction of LTP (Lisman, 1994; Blitzer et al., 1995;Thomas et al., 1996). Because strong NMDA receptor activationcan activate a signaling pathway that inhibits protein phosphatases,we investigated whether increasing levels of NMDA receptor activationby increasing the number of EPSPs that evoke complex spike burstsduring long 5 Hz stimulation trains could enable the inductionof LTP. Although we have not investigated the cellular mechanismsthat regulate complex spike bursting, EPSPs evoked complex spikebursts in a highly stereotypic manner during 5 Hz stimulation,and we found that different stimulation patterns could be usedto manipulate the total number of coincident EPSP and complexspike bursts evoked by a given number of 5 Hz stimulation pulses(Figs. 3C,D, 4). When 900 pulses of 5 Hz stimulation were deliveredas six trains of 150 pulses (intertrain interval, 20 sec) therewas a more than twofold increase in complex spike bursting in9 of 12 experiments (Fig. 4C; the percentage of EPSPs that evokedcomplex spike bursts was increased to 70% during patterned stimulationcompared with 27% during a continuous train). Consistent withthe hypothesis that increasing the amount of EPSP and complexspike burst coincidence should enable the induction of LTP duringlong trains of 5 Hz stimulation, this pattern of stimulation inducedsignificant LTP (Fig. 4D). In the three experiments in which patternedstimulation failed to enhance complex spike bursting (19% of theEPSPs evoked complex spike bursts), no LTP was observed (fEPSPswere 109.6 ± 5.2% of baseline). We also examined the effects ofdelivering 300 pulses of 5 Hz stimulation as two 150 pulse trains(intertrain interval, 10 sec). Here the EPSP and complex spikeburst coincidence was increased (73% of the EPSPs evoked complexspike bursts compared with 52% for a continuous train), and now300 pulses of 5 Hz stimulation induced LTP (fEPSPs were potentiatedto 153.8 ± 18.2% of baseline; n = 6; data not shown).

  DISCUSSION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Five hertz synaptic stimulation induces complex spike bursting in CA1 pyramidal cells

During 5 Hz synaptic stimulation, EPSPs evoked complex spike bursts in CA1 pyramidal cells in a highly activity-dependentmanner, suggesting that a complex interaction of voltage- andtransmitter-activated ion channels underlies complex spike burstgeneration. Although our experiments focused on the role of complexspike bursting in LTP induction during low-frequency synapticstimulation, some of our observations have implications regardingpotential mechanisms that might contribute to complex spike burstgeneration. First, consistent with previous findings suggestingthat a highly TTX-sensitive persistent Na⁺ conductance contributes to complex spike bursting in CA1 pyramidalcells (Azouz et al., 1996; Jensen et al., 1996), we found thata low concentration of TTX suppressed complex spike bursting.Second, our observation that synaptic stimulation reliably elicitscomplex spike bursts, whereas previous findings indicate thatdepolarization of CA1 pyramidal cells in the absence of synapticstimulation rarely elicits complex spike bursts (Jensen et al.,1994), suggests that synaptic conductances have an important rolein the generation of complex spike bursts. One possibility isthat complex spike bursting is enabled by the activity-dependentdownregulation of inhibitory synaptic transmission that occursduring theta frequency stimulation of excitatory synaptic transmissionin the hippocampal CA1 region (McCarren and Alger, 1985; Thompsonand Gähwiler, 1989; Davies et al., 1990; Pacelli et al., 1991).Indeed, whereas inhibitory synaptic potentials are partially suppressedafter the second pulse of a 5 Hz stimulation train (Davies etal., 1990; Pacelli et al., 1991), more complete suppression requires5-10 sec of stimulation (McCarren and Alger, 1985), a time thatcorresponds to the 8-10 sec delay before complex spike burstingbegins during 5 Hz stimulation observed in our experiments. Althoughdecreased inhibitory synaptic transmission may contribute to complexspike burst generation, disinhibition alone cannot account forthe pattern of complex spike bursting observed in our experiments,because complex spike bursting typically declined after 30 secof 5 Hz stimulation and ceased altogether after 1 min of stimulation(Fig. 4A), whereas inhibitory synaptic potentials remain depressedfor the duration of 5 Hz stimulation (data not shown). Synapticstimulation could also contribute to complex spike bursting byactivating postsynaptic NMDA receptors, which have been proposedto contribute to burst firing in hippocampal pyramidal cells (Abrahamand Kairiss, 1988; Poolos and Kocsis, 1990; Pongrácz et al.,1992). However, a high concentration of the NMDA receptor antagonistAPV (100 µM) did not block complex spike bursting in our experiments,suggesting that NMDA receptor activation is not required for EPSP-evokedcomplex spike bursting during 5 Hz stimulation. Clearly, muchremains to be discovered regarding the synaptic and cellular mechanismsresponsible for the activity-dependent pattern of complex spikebursting elicited by 5 Hz trains of synaptic stimulation. However,the ability of 5 Hz synaptic stimulation to reliably elicit complexspike bursts in the hippocampal slice preparation should facilitatea more in-depth analysis of this phenomenon.

Complex spike bursts enable the induction of LTP during 5 Hz stimulation

Recent studies investigating phenomena ranging from the elementary properties of synaptic transmission to the behavioral correlatesof single-unit firing in vivo suggest that the complex spike modeof action potential firing in hippocampal pyramidal cells representsan informationally rich form of neuronal activity (for review,see Lisman, 1997). For instance, hippocampal pyramidal cells areoften preferentially activated when animals enter specific locationswith the environment (O'Keefe and Dostrovsky, 1971; O'Keefe, 1976;Muller, 1996), and the region in which a given cell is maximallyactivated, called its place field, is more precisely defined bycomplex spike bursting than by single spikes (Otto et al., 1991).Complex spike bursting in ensembles of hippocampal neurons maythus generate a more accurate internal representation of positionin the external environment than single spikes (Lisman, 1997).In our experiments we found that (1) LTP is induced by strong-intensity5 Hz synaptic stimulation that evokes postsynaptic complex spikebursting but not by weak-intensity 5 Hz stimulation that failsto evoke complex spike bursts; (2) LTP is blocked by low concentrationsof TTX that have little effect on the generation of single postsynapticaction potentials but block complex spike bursting; (3) strong-intensity5 Hz stimulation trains that terminate before complex spike burstingbegins fail to induce LTP; (4) LTP is induced by pairing synapticpotentials with simulated complex spike bursts evoked by antidromicstimulation but not by pairing EPSPs with single antidromic actionpotentials; (5) the induction of LTP is inhibited by patterningstimulation protocols to reduce complex spike bursting duringshort trains of 5 Hz stimulation; and (6) patterned stimulationprotocols that increase complex spike bursting during long trainsof 5 Hz stimulation enable LTP induction. Our results thus indicatethat, in addition to their proposed role in information coding,postsynaptic complex spike bursts also have an important rolein synaptic plasticity.

Although the patterns of neuronal activity that induce LTP in vivo are unknown, previous studies have shown that patternsof presynaptic fiber stimulation that mimic complex spike burstingcan induce LTP. For instance, LTP can be induced in vitro by presynapticbursts of high-frequency stimulation delivered at the theta frequency(Larson et al., 1986) or in phase with carbachol-induced thetafrequency-like activity (Huerta and Lisman, 1993, 1995). Likewise,bursts of high-frequency presynaptic stimulation applied duringthe positive phase of the theta rhythm in vivo induce robust LTP(Hölscher et al., 1997). Our results indicate that in additionto this potential presynaptic role for complex spike bursting,postsynaptic complex spike bursts enable the induction of LTPin the absence of presynaptic bursting. One possibility suggestedby our findings is that back-propagating action potentials duringpostsynaptic complex spike bursting in vivo (Buzáki et al., 1996)produce a state of heightened sensitivity during which even lowfrequencies of presynaptic activity can readily induce LTP. Becauseaction potentials can be initiated in pyramidal cell dendritesunder some conditions (Spencer and Kandel, 1961; Wong et al.,1979; Poolos and Kocsis, 1990; Turner et al., 1991; Spruston etal., 1995), our results do not rule out the possibility that dendriticallyinitiated, rather than back-propagating, complex spike burstsproduce such an effect.

Because brief trains of 5 Hz stimulation (75 and 150 pulses) induce LTP, our results indicate that unpotentiated synapsesthat are coactive with postsynaptic complex spike bursts willreadily undergo LTP, even when relatively few EPSPs evoke complexspike bursts. In contrast, little LTP was induced by longer trainsof continuous 5 Hz stimulation (300 and 900 pulses), even thoughthe total number of EPSP-evoked complex spike bursts was severaltimes greater than that elicited by shorter trains of 5 Hz stimulation.LTP could be induced by long trains of 5 Hz stimulation when patternedstimulation was used to increase the number of EPSP-evoked complexspike bursts. Thus, the amount of coincident presynaptic and postsynapticactivity (EPSP-evoked complex spike bursts) required to induceLTP increases during 5 Hz stimulation in a manner similar to thatpredicted by the BCM (Bienenstock, Cooper, Muro) model of synapticplasticity (Bear et al., 1987), which proposes that the thresholdlevel of coincident synaptic activity needed to induce persistentincreases in synaptic strength increases with the induction ofLTP. Because previous studies have shown that protein phosphataseinhibitors enable the induction of LTP during long trains of 5Hz stimulation (Thomas et al., 1996), an activity-dependent activationof protein phosphatases may underlie the need for increased levelsof EPSP and complex spike burst coincidence to induce LTP duringlong trains of 5 Hz stimulation. Physiologically, this need forhigher levels of coincident EPSP and complex spike bursts to induceLTP as stimulation extends beyond that minimally required forLTP induction may act to restrict LTP to only those synapses thatreliably evoke complex spike bursting (Fig. 4, compare A,C andD). Thus, LTP induced by EPSP-evoked complex spike bursting duringlow-frequency stimulation is truly Hebbian (Hebb, 1949); it notonly requires postsynaptic action potentials but, at least forlong-duration trains, also requires that EPSPs consistently contributeto postsynaptic bursting.

Hippocampal pyramidal cells often fire complex spike bursts when animals occupy specific locations within the environment(Ranck, 1973; Muller, 1996). Although place-specific firing ofpyramidal cells is probably generated endogenously via locomotorcues that provide information about position in the external environment,synaptic inputs that convey place-specific sensory informationabout the environment are thought to become linked, or bound,to firing of a particular place cell through a process such asLTP (McNaughton et al., 1996). Our results, which show that synapticinputs active during complex spike bursting undergo robust LTP,suggest how this latter process may occur in vivo and providea cellular basis for understanding how the theta frequency complexspike bursting observed in CA1 pyramidal cells during behaviorsassociated with learning (Otto et al., 1991) might contributeto memory formation.

  FOOTNOTES

Received April 3, 1998; revised June 18, 1998; accepted June 26, 1998.

This work was supported by grants from the National Institute of Mental Health, the Klingenstein Fund, and the Pew CharitableTrusts to T.J.O. T.J.O. is a member of the University of CaliforniaLos Angeles Brain Research Institute. We are grateful to D. V.Buonomano, D. Glanzman, and F. Krasne for comments on an earlierversion of this manuscript.
M.J.T. and A.M.W. made equal contributions to this work.

Correspondence should be addressed to Dr. Thomas O'Dell, Department of Physiology, University of California Los Angeles Schoolof Medicine, 53-231 Center for the Health Sciences, 10833 Le ConteAvenue, Los Angeles, CA 90095.

  REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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