Cholinergic Induction of Theta-Frequency Oscillations in Hippocampal Inhibitory Interneurons and Pacing of Pyramidal Cell Firing

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The Journal of Neuroscience, October 1, 1999, 19(19):8637-8645

Cholinergic Induction of Theta-Frequency Oscillations in Hippocampal Inhibitory Interneurons and Pacing of Pyramidal Cell Firing
C. Andrew Chapman and Jean-Claude Lacaille
Centre de Recherche en Sciences Neurologiques et Département de Physiologie, Université de Montréal, Montréal, Québec, H3C 3J7 Canada

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cholinergic and GABAergic medial septal afferents contribute to hippocampal theta activity in part by actions on local interneurons.Interneurons near the border between stratum radiatum and stratumlacunosum-moleculare (LM) display intrinsic membrane potentialoscillations at theta frequency when depolarized near threshold.First, whole-cell current-clamp recordings in rat hippocampalslices were used to examine effects of the cholinergic agonistcarbachol on biocytin-labeled LM interneurons. At resting membranepotential, cells were depolarized by bath application of 25 µMcarbachol, and the depolarization was sufficient to induce membranepotential oscillations (2.4 ± 0.2 mV) that paced cell firing.Carbachol also depolarized LM interneurons in the presence of6-cyano-7-nitroquinoxaline-2,3-dione, (±)-2-amino-5-phosphonopentanoicacid, and bicuculline, indicating that cholinergic depolarizationof LM cells does not depend on ionotropic glutamate or GABA_A synaptictransmission in local circuits. Atropine blocked the depolarization,indicating that muscarinic receptors were involved. Minimal stimulationapplied to visually identified LM interneurons was then used todetermine if spontaneous activity in CA1 pyramidal cells can bepaced by rhythmic inhibition generated by LM cells at theta frequency.Inhibitory postsynaptic potentials evoked in pyramidal cells bysingle minimal stimulations were followed by rebound depolarizationsand action potentials. When trains of minimal stimulation weredelivered, membrane potential oscillations of depolarized pyramidalcells followed the stimulation frequency. Minimal stimulationled pyramidal cell firing with an average phase of 177°. Thus,muscarinic induction of theta-frequency membrane potential oscillationsin LM interneurons may contribute to the generation of rhythmicinhibition that paces intrinsically generated theta activity inCA1 pyramidalcells.

Key words: hippocampus; lacunosum-moleculare; theta; rhythmic slow activity; interneurons; cholinergic; GABA

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Rhythmic synchronization of principal cells in hippocampus and entorhinal cortex generates theta-frequency (4-12 Hz) electroencephalographicactivity, and is thought to govern temporal integration of synapticinputs (Singer, 1993; Buzsáki and Chrobak, 1995) and mechanismsmediating memory formation (Larson et al., 1986; Huerta and Lisman,1995; Chapman and Racine, 1997; Chapman et al., 1998; Perez etal., 1999). Hippocampal inhibitory interneurons play a centralrole in theta activity by rhythmically inhibiting pyramidal cells(Leung, 1984; Fox, 1989; Ylinen et al., 1995; Tóth et al., 1997).GABA_A chloride conductances are activated during each theta cycle(Fox et al., 1983; Leung and Yim, 1986; Buzsáki et al., 1986;Soltesz and Deschênes, 1993; Ylinen et al., 1995), and rhythmicstimulation of basket and axo-axonic interneurons sets the phaseof theta in pyramidal cells in vitro (Cobb et al., 1995).

Different subtypes of hippocampal interneurons (Sik et al., 1995; Freund and Buzsáki, 1996) contribute preferentially todifferent local circuit interactions and rhythmic activities.Interneurons with soma in stratum pyramidale or oriens mediatefast feedback inhibition, fire at high rates (Schwartzkroin andMathers, 1978; Lacaille et al., 1987; Lacaille and Williams, 1990),and may contribute to both theta (Cobb et al., 1995; Csicsvariet al., 1999) and gamma (Whittington et al., 1995; Wang and Buzsáki,1996) activity. Interneurons located near the border of strataradiatum and lacunosum-moleculare (LM) receive less spontaneoussynaptic input, fire at slower rates (Lacaille and Schwartzkroin,1988a,b), and mediate slowly decaying dendritic inhibition (Ouardouzand Lacaille, 1997; Banks et al., 1998). When LM cells are depolarizednear threshold, they show theta-frequency membrane potential oscillations(Lacaille and Schwartzkroin, 1988a; Williams et al., 1994) generatedby an interplay between intrinsic voltage-dependent Na⁺ and K⁺ conductances (Chapman and Lacaille, 1999). Rhythmic inhibitionpaced by LM cell oscillations may therefore entrain theta activityin pyramidalneurons.

Medial septal afferents drive hippocampal theta activity (Green and Arduini, 1954; Bland and Colom, 1993), and inputs ontointerneurons may play a large role. Cholinergic septal afferentscontact interneurons and pyramidal cells (Léránth and Frotscher,1987), and GABAergic inputs target predominantly interneurons(Freund and Antal, 1988; Gulyás et al., 1990). GABAergic afferentsmay disinhibit pyramidal cells during each theta cycle by inhibitingtonically active interneurons (Tóth et al., 1997). Cholinergicagonists induce theta-like activity in the in vitro hippocampus(Konopacki et al., 1987; MacVicar and Tse, 1989), and cholinergicexcitation of interneurons (Reece and Schwartzkroin, 1991a; Pitlerand Alger, 1992; Behrends and ten Bruggencate, 1993) may helpsynchronize this activity (Williams and Kauer, 1997; McMahon etal., 1998).

To investigate if cholinergic depolarization of LM interneurons evokes rhythmic inhibition that paces theta activity in pyramidalcells, effects of carbachol on membrane potential oscillationsin LM interneurons were examined using whole-cell current-clamprecordings in rat hippocampal slices. The ability of LM cellsto regulate theta-frequency activity in pyramidal cells was thenassessed by monitoring pyramidal cell activity during minimalstimulation of stratum lacunosum-moleculare.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Methods were similar to those reported previously (Chapman and Lacaille, 1999), and all chemicals were obtained from Sigma(St. Louis, MO), unless otherwiseindicated.

Hippocampal slices. Hippocampal slices were obtained from 4- to 6-week-old Sprague Dawley rats (Charles River, Montréal,Québec, Canada) anesthetized with halothane (Halocarbon Laboratories,River Edge, NJ). After decapitation, the brain was quickly removedand placed in cold (4°C) artificial CSF (ACSF) containing (inmM) 124 NaCl, 5 KCl, 1.25 NaH₂PO₄, 2 MgSO₄, 2.4 CaCl₂, 26 NaHCO₃,and 10 dextrose saturated with 95% O₂ and 5% CO₂. Transverse hippocampalslices (300-µm-thick) were cut using a vibratome and stored atroom temperature for at least 1hr.

Slices were held submerged in a recording chamber and viewed with an upright microscope (Carl Zeiss Axioskop, Jena, Germany)equipped with Hoffman optics (Modulation Optics, Greenvale, NY),a long-range water immersion objective (40×), and an infraredvideo camera (model 6500; Cohu, San Diego, CA). The chamber wasperfused with ACSF at room temperature (22°C) at a rate of 2.5-3.0ml/min.

Whole-cell recording. Patch pipettes (4-7 M $Omega$ ) were pulled from borosilicate glass (1.0 mm outer diameter) and filled witha solution containing (in mM) 140 K-gluconate, 5 NaCl, 2 MgCl₂,10 HEPES, 0.5 EGTA, 2 ATP-Tris, 0.4 GTP-Tris, and 0.1% biocytin,pH adjusted to 7.2-7.3 with KOH. Tight seals (2-6 G $Omega$ ) were obtainedon LM interneurons or CA1 pyramidal cells using gentle suction,and whole-cell current-clamp recordings were begun 5 min afterbreak-in. Membrane potential recordings (DC to 3 kHz) were obtainedwith an Axoclamp 2A amplifier (Axon Instruments, Foster City,CA), displayed on a digital oscilloscope (model 1604; Gould, Ilford,UK), and digitized for storage on video cassette (NeuroCorderDR-886; NeuroData, New York, NY). Recordings were analog-filteredat 1 kHz (model 900, 8 pole bessel filter; Frequency Devices,Haverville, MA), and digitized at 10 kHz (TL-1; Axon Instruments)for storage on computer hard disk. Recordings were accepted ifseries resistance was <50 M $Omega$ (interneurons: mean, 32.0 ± 1.5 M $Omega$ ;pyramidal cells: mean, 32.6 ± 4.1 M $Omega$ ) and input resistance wasstable. Series resistance was monitoredrepeatedly.

Pharmacology. Cholinergic effects on resting membrane potential and firing properties of LM interneurons were assessed with2-5 min bath applications of the cholinergic agonist carbachol(25 µM). Voltage-dependent changes in frequency and amplitudeof oscillations were monitored using steady current injectionto hold LM cells at various membrane potentials relative to spikethreshold both before and during carbachol application. Voltageresponses to positive and negative current pulses (500 msec duration)were also recorded in the presence and absence ofcarbachol.

To determine if carbachol-induced depolarization of LM cells results from changes in local circuit synaptic inputs, carbacholwas applied 20 min after bath application of 6-cyano-7-nitroquinoxaline-2,3-dione(CNQX; 20 µM), (±)-2-amino-5-phosphonopentanoic acid (AP-5; 50µM; Research Biochemicals, Natick, MA), and bicuculline methiodide(25 µM) to block ionotropic glutamate and GABA_A synaptic transmission.To determine if muscarinic receptors mediate carbachol-induceddepolarization, the muscarinic receptor antagonist atropine (1µM) was applied for a 15-20 min period before addingcarbachol.

Minimal stimulation. The impact of inhibition generated by LM cell firing at theta frequency on firing activity in pyramidalneurons was assessed using minimal stimulation in stratum lacunosum-moleculareduring whole-cell current-clamp recordings from CA1 pyramidalneurons in the presence of CNQX and AP-5. Bipolar borosilicatetheta glass stimulation electrodes (Sutter Instruments) filledwith ACSF were placed in stratum lacunosum-moleculare 100-200µm from the soma of visually identified LM interneurons. Stimulationintensity was adjusted (56-128 µA) to evoke IPSPs with failurerates of ~33%. Steady positive current injection was used to depolarizepyramidal neurons to induce spontaneous membrane potential oscillationsand action potentials. First, single pulses of minimal stimulationwere delivered once every 10 sec to characterize IPSPs and theireffects on pyramidal cell firing. Then, 2.0 sec duration trainsof minimal stimulation were used to determine if firing propertiesof pyramidal cells may be paced repetitively by minimal stimulationof stratum lacunosum-moleculare. The frequency of minimal stimulationwas set to 3 Hz to match the frequency of spontaneous activityin LM interneurons (Chapman and Lacaille, 1999) and pyramidalcells at 22°C. Bicuculline (20 µM) was added to the bath, andchanges in minimal IPSPs at resting membrane potential were monitoredto determine GABA_A receptorinvolvement.

Analysis. Samples of membrane potential in LM cells were prepared for spectral analysis as described previously (Chapman andLacaille, 1999) by low-pass filtering at 100 Hz and reducing theeffective sampling rate to 1 kHz. Average power spectra were calculatedas the squared magnitude of the Fast Fourier Transform using theOrigin software package (Microcal, Northampton, MA) based on three2.048 sec duration segments selected to contain no action potentials.Matched samples t tests were used to compare oscillation peakfrequency and power in the 2-5.4 Hz band in the presence and absenceof carbachol. Changes in the firing of pyramidal cells were assessedby measuring latencies of action potentials relative to minimalstimulation. Rhythmicity of pyramidal cell membrane potentialwas assessed using autocorrelation functions obtained from 2.0sec duration, digitally filtered (40 Hz) records of membrane potentialrecorded just before, and during, trains of minimalstimulation.

Electrophysiological properties of LM interneurons and pyramidal cells were analyzed using the software package pClamp 6.0(Axon Instruments). Action potential height was measured fromresting membrane potential, and action potential duration wasmeasured at the base. Afterhyperpolarization amplitudes were measuredrelative to the base of action potentials. Input resistance wasquantified by the slope of a linear fit of peak voltage responsesto current pulses (500 msec duration) ranging from $-$ 100 to 0 pAin steps of 10 pA. Inward rectification was quantified by expressingthe peak input resistance as a proportion (rectification ratio)of steady-state resistance measured at the end of 500 msec duration, $-$ 100 pA current pulses. Membrane time constant was measured byfitting an exponential function to the transient voltage responseevoked by small hyperpolarizing current pulses that did not evokehyperpolarization-activatedrectification.

Histology. Detailed histological procedures for revealing biocytin-filled cells have been described previously (Chapman andLacaille, 1999). Briefly, slices were fixed in 4% paraformaldehydein 0.1 M phosphate buffer, rinsed, and stored at 4°C before resectioningto a thickness of 60 µm. Sections were treated with 1% H₂O₂, washedin 2.5% dimethylsulfoxyde and 0.1% Triton X-100 in 0.1 M phosphatebuffer, and incubated in avidin-biotin complex (ABC kit; VectorLaboratories, Burlingame, CA). After rinsing, sections were incubatedin 0.05% 3'3-diaminobenzidine 4 HCl, 0.02% NiS0₄, 0.1 M imidazole,and 0.001% H₂O₂ in Tris-buffered saline. Sections were then rinsedand cleared in xylene. Axonal and dendritic arborizations of well-filledcells were traced with a cameralucida.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Basic electrophysiology and morphology of LM interneurons

Stable recordings were obtained from 27 LM cells. Passive electrical properties and firing patterns of LM cells were similarto whole-cell recordings reported previously (Williams et al.,1994; Chapman and Lacaille, 1999). LM cells were typically silentat resting membrane potential (mean, $-$ 55.6 ± 0.7 mV), had highinput resistances (283 ± 18 M $Omega$ ), and long membrane time constants( $tau$ _m = 25.0 ± 1.7 msec). Action potentials (amplitude, 95.6 ± 0.8mV; duration, 2.8 ± 0.1 msec) were typically followed by fast(9.4 ± 0.6 mV) and medium duration (12.2 ± 0.7 mV) afterhyperpolarizations.Inward rectification was observed in 13 of 27 cells, and the meanrectification ratio among these cells was 1.12 ± 0.02 (range,1.03-1.25).

Morphological information was obtained for 21 biocytin-filled LM interneurons. Morphology of LM cells was similar to thatreported previously (Williams et al., 1994; Morin et al., 1996;Chapman and Lacaille, 1999) (Figs. 1E, 2C), except that axonalor dendritic arborizations were not observed outside the CA1 area.Also, neuroglioform cells in LM (Vida et al., 1998) were not observed.Somata of LM cells (10-25 µm diameter) were either multipolar(12 cells) or fusiform in shape and oriented parallel to the pyramidalcell layer (nine cells). Cells had between two and five primarydendrites that bifurcated close to the soma and arbourized instratum radiatum and lacunosum-moleculare. Six multipolar cellshad dendrites that extended into stratum oriens. Axonal arbourizationswere reconstructed in 14 cells and arborized mainly in stratumradiatum and stratum lacunosum-moleculare. Four cells also showedsome axonal arbourizations in stratum pyramidale (three cells)and stratum oriens (two cells).

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Figure 1. Carbachol depolarizes LM interneurons and induces voltage-dependent membrane potential oscillations. A,B, Membrane potential recording from an LM interneuron exposed to the cholinergic agonist carbachol (CCh, solid bar; 25 µM). Letters in A indicate times from which expanded traces in B were taken, and action potentials are truncated in this and subsequent figures. Voltage-dependent oscillations were induced in the LM cell with positive current injection before carbachol application (B, top left trace). Application of carbachol at resting membrane potential (a) was followed by a depolarization that induced oscillations that paced action potentials (b, d). The depolarization was preceded by a small transient hyperpolarization (see also Fig. 2A). Oscillations induced by carbachol were eliminated when the cell was hyperpolarized with steady negative current injection (c) or when the cell repolarized after washout of carbachol (e), indicating that the oscillations are voltage-dependent. C, Power spectral analysis of oscillations in six LM cells in which membrane potential relative to spike threshold was varied using steady current injection. Frequency and amplitude of oscillations, and their voltage dependence, were not significantly different in carbachol (dashed lines) and in normal ACSF (solid lines). D, Voltage responses to positive and negative current pulses that ranged from $-$ 100 to 60 pA in 10 pA steps. For this cell, carbachol increased input resistance and decreased afterhyperpolarization amplitude. E, Camera lucida tracing of the LM interneuron from which recordings in A, B, and D were obtained. The axon is indicated by an arrow. Abbreviations in this figure and in Figure 2: Or, stratum oriens; Pyr, stratum pyramidale; Rad, stratum radiatum; L-M, stratum lacunosum-moleculare.

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Figure 2. Glutamate and GABA_A synaptic activity are not necessary for the depolarization of LM interneurons induced by carbachol. A, B, Membrane potential of an LM interneuron exposed to bath application of 25 µM carbachol (CCh, solid bar) during blockade of ionotropic glutamate and GABA_A synaptic transmission with CNQX (20 µM), AP-5 (50 µM), and bicuculline (25 µM). Letters indicate times from which expanded traces in B were taken. Steady current injection induced voltage-dependent oscillations before carbachol application (B, top left trace). Application of carbachol at resting membrane potential (a) was followed by a transient hyperpolarization (b), and then a depolarization that induced oscillations and cell firing (c). C, Camera lucida tracing of the LM interneuron from which recordings were obtained. The axon is indicated by an arrow.

Oscillations in LM interneurons induced by carbachol

When positive current injection (usually <40 pA) was used to hold LM cells near spike threshold, almost all cells (25 of 27cells) displayed voltage-dependent membrane potential oscillationswith a frequency of 2-5 Hz. LM cells fired either single spikesor clusters of action potentials at the frequency of oscillations(Fig. 1B, top left trace).

At resting membrane potential, addition of 25 µM carbachol (CCh) to the bath resulted in a depolarization of 1-9 mV (mean,4.1 ± 0.7 mV) in 14 of 16 LM interneurons (Fig. 1A). Depolarizingresponses peaked 134 ± 20 sec (range, 40-225 sec) after applicationof carbachol. In eight cells, the depolarization was precededby a transient hyperpolarization of 1-7 mV (mean, 4.2 ± 0.6 mV)that peaked at a mean latency of 58 ± 8 sec. The carbachol-induceddepolarization was sufficient to result in membrane potentialoscillations (2.4 ± 0.2 mV peak-to-peak) and action potentialgeneration in 12 cells (Fig. 1B, traces b, d). In three cells,strong depolarizations resulted in high-frequency spiking between10 and 29 Hz. Membrane potential oscillations during carbacholapplication were eliminated when cells were repolarized to restingmembrane potential with negative current injection, indicatingthat oscillations induced by carbachol were voltage-dependent(Fig. 1B, trace c). Membrane potential of LM cells returned towardresting membrane potential after 15-20 min washout in normal ACSF(Fig. 1A, Be).

Oscillations induced by carbachol were similar to those induced in normal ACSF by depolarizing current injection. Oscillationsin carbachol and in normal ACSF did not differ with respect topower (control, 2.31 ± 0.33 mV²/Hz; CCh, 2.18 ± 0.35 mV²/Hz) or peak frequency (control, 3.4 ± 0.2 Hz; CCh, 3.2 ± 0.2Hz). Furthermore, when membrane potential was varied systematicallywith current injection, reductions in oscillation power and frequencyas a function of hyperpolarization from spike threshold were similarin both carbachol and in normal ACSF (Fig. 1C).

Changes in input resistance induced by carbachol were not consistent and did not predict the degree of depolarization induced.Input resistance was increased in six cells (range, 8-67%; mean,26.6 ± 9.4%), reduced in five cells (range, $-$ 6.9 to $-$ 23.8%; mean,13.1 ± 3.2%), and changed less than ±5% in five cells. Carbacholalso produced no significant changes in amplitude of fast durationafterhyperpolarizations (fAHPs) or medium duration afterhyperpolarizations(mAHPs) in LM cells (fAHP: control, 9.4 ± 0.6 mV; CCh, 8.0 ± 0.7mV; mAHP: control, 12.2 ± 0.7 mV; CCh, 10.5 ± 0.8 mV) (Fig. 1D).Carbachol reduces amplitude and increases duration of action potentialsin pyramidal neurons (Figenschou et al., 1996) but these changeswere not statistically significant in LM interneurons (amplitude:control, 95.6 ± 0.8 mV; CCh, 92.9 ± 4.7 mV; t₃₀ = 1.89, p = 0.07;duration: control, 2.8 ± 0.2 msec; CCh, 3.0 ± 0.5 msec; t₃₀ =1.78, p = 0.09).

Receptors mediating cholinergic depolarization of LM interneurons

To determine if glutamatergic and GABAergic synaptic activity in local circuits could mediate cholinergic depolarization ofLM cells, experiments were also conducted in the presence of theglutamate and GABA_A receptor blockers CNQX (20 µM), AP-5 (50 µM),and bicuculline (25 µM; n = 7; Fig. 2). In all cells, carbacholinduced a depolarization of membrane potential similar in amplitude(range, 2-10 mV; mean, 6.1 ± 1.0 mV) to that observed in normalACSF. In three of seven cells, application of carbachol in thepresence of these antagonists resulted in an initial transienthyperpolarization (range, 4-10 mV; e.g., Fig. 2A,B, compare a,b).The hyperpolarizing and depolarizing responses induced by carbacholtherefore do not depend on glutamatergic and GABAergic synapticactivity in local circuits. Power and frequency of membrane potentialoscillations in CNQX, AP-5, and bicuculline were not differentfrom those recorded in normal ACSF, whether they were inducedby positive current injection (frequency, 3.1 ± 0.3 Hz; power,2.34 ± 0.6 mV²/Hz; see also Chapman and Lacaille, 1999) or by carbachol (frequency,3.1 ± 0.2 Hz; power, 2.6 ± 0.7 mV²/Hz). Membrane potential of LM cells returned to resting membranepotential following washout of carbachol (Fig. 2A,B, compare c,d).

To determine if muscarinic receptors on LM interneurons mediate depolarizations induced by carbachol, the muscarinic receptorantagonist atropine (1 µM) was added to the bath 15-20 min beforethe addition of carbachol. Atropine blocked depolarizations inducedby carbachol (n = 5; Fig. 3A,B vs C,D, compare a,b), and the meanchange in membrane potential was $-$ 0.8 ± 0.6 mV (range, $-$ 2-2 mV).Carbachol-induced depolarizations in normal ACSF were thereforemediated by activation of muscarinic cholinergic receptors.

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Figure 3. Muscarinic receptors mediate the depolarization of LM interneurons induced by carbachol. Membrane potential of an LM interneuron exposed to a 2 min bath application of 25 µM carbachol (CCh, solid bar) in normal ACSF (A, B) and in the presence of the muscarinic receptor antagonist atropine (C, D, open bar; 1 µM). Letters in A and C indicate times from which the corresponding traces in B and D were taken. Steady current injection induced voltage-dependent oscillations in normal ACSF before carbachol application (B, top left trace). In normal ACSF, carbachol depolarized the cell from resting membrane potential and induced voltage-dependent oscillations and cell firing (A, a vs b). Oscillations were eliminated during washout of carbachol as membrane potential repolarized (c). After exposure to atropine for at least 15 min (C, D), carbachol did not induce oscillations or cell firing (C, a vs b).

Minimal IPSPs in CA1 pyramidal neurons

To determine how inhibition generated by LM cells affects firing patterns of pyramidal cells, whole-cell current clamp recordingswere obtained from CA1 pyramidal cells in the presence of CNQXand AP-5, and minimal stimulation was applied to stratum lacunosum-moleculareclose to visually identified LM interneurons. Biocytin labelingwas successful for 8 of the 10 pyramidal cells, and each showedbasal and apical dendritic arbourizations characteristic of pyramidalneurons (data not shown; see Morin et al., 1996). Basic electrophysiologicalcharacteristics of cells were also consistent with whole-cellrecordings from pyramidal neurons (resting membrane potential, $-$ 54.1 ± 0.8 mV; input resistance, 144 ± 7 M $Omega$ ; $tau$ _m = 37.3 ± 2.1msec; rectification ratio, 1.27 ± 0.02; action potential amplitude,95.3 ± 1.4 mV; action potential duration, 3.6 ± 0.1 msec; mAHPamplitude, 4.4 ± 0.8mV).

To stimulate inhibitory afferents to pyramidal cells originating from single interneuron fibers in LM, the stimulating electrodewas placed near a visually identified LM interneuron, and stimulationintensity was adjusted to evoke IPSPs in pyramidal cells witha large proportion of failures (23-43%). Minimally evoked IPSPsat resting membrane potential had a mean peak amplitude of $-$ 0.63± 0.06 mV, a peak latency of 57 ± 4 msec, and decayed monoexponentiallywith long decay time constants (77 ± 6 msec; Fig. 4A, bottom trace).Bath application of 25 µM bicuculline at the end of experimentsblocked minimal IPSPs (eight of eight cells), indicating theirdependence on GABA_A receptor activation.

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Figure 4. Minimal stimulation in stratum lacunosum-moleculare evokes IPSPs, followed by rebound depolarization and spiking in CA1 pyramidal neurons. A, IPSPs evoked in pyramidal cells by minimal stimulation in stratum lacunosum-moleculare (arrows) at membrane potentials indicated at left. Eleven superimposed traces (A, top) show minimal IPSPs that were followed by an action potential. Rebound depolarizations at the same latencies as the action potentials were also observed when the cell was held just below spike threshold (A, middle, mean of 12 traces), but not at more hyperpolarized levels (A, bottom, mean of 61 traces). B₁, Fifty superimposed traces showing the effect of minimally evoked IPSPs (arrow) on firing of the CA1 pyramidal cell. B₂, The corresponding spike frequency histogram shows peaks at latencies near 250 and 600 msec, suggesting that intrinsic mechanisms generating rhythmic membrane potential oscillations in the pyramidal cell are reset by minimal IPSPs generated from stratum lacunosum-moleculare.

To determine how minimal IPSPs affect firing behavior of pyramidal cells, single pulses of minimal stimulation were deliveredduring positive current injection used to depolarize pyramidalcells to action potential threshold. The peak latency of minimalIPSPs (56 ± 3 msec) was unchanged, but amplitudes of minimal IPSPsin depolarized pyramidal cells ( $-$ 1.28 ± 0.18 mV) were roughlytwice as large as at resting membrane potential. Action potentialsin pyramidal cells were suppressed during the IPSP for a meanduration of 81 ± 6 msec, and the decay of minimal IPSPs was usuallyfollowed by a transient rebound depolarization in which membranepotential overshot the mean resting membrane potential to moredepolarized levels. On trials in which the IPSP was followed byan action potential, the latency of the first spike was ~250-300msec; similar to the peak latency of the rebound depolarization(Fig. 4A, top traces). Therefore, single minimal IPSPs first suppressedpyramidal cell firing and then induced a rebound depolarizingresponse that timed firing of action potentials. Visual inspectionof spike frequency histograms identified peaks reflecting themean latency of rebound action potentials in pyramidal cells (275± 19 msec; n = 10 cells). In 5 of 10 cells there was a secondclear peak at a mean latency of 644 ± 32 msec, suggesting thatminimal IPSPs generated by LM interneurons can reset intrinsicoscillatory activity pyramidal cells (Fig. 4B).

To determine how repetitive firing of pyramidal cells may be affected by rhythmic inhibition generated by LM interneurons,trains of minimal stimulation were delivered in stratum lacunosum-moleculareclose to visually identified LM cells. Two second duration trainswere delivered at a frequency of 3 Hz to match the frequency ofspontaneous oscillatory activity in LM cells at 22°C. The phaseof repetitive pyramidal cell firing was strongly affected duringtrains of minimal stimulation (Fig. 5). Minimal IPSPs generatedduring the train of minimal stimulation caused an initial depressionof cell firing lasting 63 ± 7 msec on average, and subsequentaction potentials were generated with a mean latency of 197 ±5 msec relative to pulses in the trains. Peaks in spike frequencyhistograms (20 msec bins) indicated that action potentials occurredwith the highest probability at a mean latency of 164 ± 12 msec.Pyramidal cell firing was therefore generated with a phase relationshipof 177° relative to trains of minimal stimulation at 3 Hz.

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Figure 5. Low-frequency minimal stimulation of stratum lacunosum-moleculare paces repetitive firing of pyramidal neurons. A₁, Seventy superimposed traces showing the effect of a 3 Hz train of minimal stimulation (arrows) on the firing of a CA1 pyramidal cell depolarized to threshold by steady current injection. A₂, The corresponding spike frequency histogram shows that the timing of low-frequency spiking in the pyramidal cell is paced throughout the train of minimal stimulation in stratum lacunosum-moleculare. On average, the firing of pyramidal cells was ~180° out of phase with the minimal stimulation at 3 Hz. B, Increased rhythmicity of pyramidal cell firing (B₁) is reflected in autocorrelation functions of 2 sec recordings of membrane potential obtained just before (B₂) and during (B₃) the train of minimal stimulation.

Comparison of autocorrelation functions of 2 sec samples of membrane potential recorded before and during trains of minimalstimulation showed that the trains also enhanced the rhythmicityof low-frequency oscillatory activity in pyramidal cell membranepotential (Fig. 5B₁, B₂, B₃). Autocorrelation functions were increasedin amplitude and showed much more regular peaks for membrane potentialrecorded during minimal stimulation. Furthermore, peaks in theautocorrelation functions separated by ~333 msec indicated thatpyramidal cell membrane potential was entrained to the 3 Hz stimulationfrequency.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Hippocampal CA1 interneurons with their soma near the border of stratum radiatum and stratum lacunosum-moleculare displayintrinsic voltage-dependent membrane potential oscillations attheta-frequency that are dependent on an interplay between Na⁺ and K⁺ conductances (Chapman and Lacaille, 1999). First, we have shownhere that LM interneurons are depolarized by the cholinergic agonistcarbachol through direct activation of muscarinic receptors onLM cells. Cholinergic depolarization of LM interneurons inducedvoltage-dependent oscillations that paced cell firing, thereforegenerating rhythmic inhibitory input to pyramidal cell dendrites.Second, minimal stimulation of stratum lacunosum-moleculare wasused to mimic the rhythmic dendritic inhibition generated by LMcells, and minimal IPSPs were found to pace firing patterns ofpyramidal neurons. Single minimal stimulations evoked slowly decayingIPSPs that were followed by rebound depolarizations that timedfiring of action potentials. Furthermore, the phase of membranepotential oscillations in pyramidal cells was effectively setduring trains of minimal stimulation. These results indicate animportant role for LM interneurons in pacing theta activity inpyramidal cells and suggest that the cholinergic activation ofLM interneurons may be a powerful mechanism through which themedial septum contributes to the generation of coordinated theta-frequencyactivity in the hippocampus in vivo (Fig. 6).

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Figure 6. Schematic diagram indicating how LM interneurons can contribute to the pacing of theta activity in CA1 pyramidal neurons. CA1 pyramidal cells (PYR) are shown to receive excitatory cholinergic inputs (+) from the medial septum, whereas LM interneurons receive both cholinergic and inhibitory GABAergic ( $-$ ) septal inputs. The proposed relationship between membrane potential (V_m) in LM cells and pyramidal cells during theta activity is indicated by the traces above each cell. In the model, cholinergic septal afferents depolarize both LM cells and pyramidal cells and induce intrinsic theta-frequency membrane potential oscillations in LM cells that pace action potential generation. Generation of dendritic IPSPs at theta frequency by LM interneurons paces the intrinsic oscillatory activity of the pyramidal cell such that it is ~180° out of phase with the firing of LM interneurons. Furthermore, because each LM interneuron contacts many pyramidal cells, rhythmic firing of single LM interneurons may synchronize theta activity among large numbers of pyramidal cells. Synchronization of theta-frequency oscillations among LM interneurons may be accomplished in part by GABAergic inputs from the medial septum through a mechanism similar to that proposed for the pacing of theta activity in pyramidal cells by LM interneurons.

Oscillations in LM interneurons induced by carbachol

Carbachol induced voltage-dependent membrane potential oscillations in LM interneurons by depolarizing membrane potential.The depolarization did not result from cholinergic effects oncells providing major excitatory and inhibitory synaptic inputsto LM interneurons (Cole and Nicoll, 1984; MacVicar and Tse, 1989;McMahon et al., 1998), because the depolarization was not blockedwhen ionotropic glutamate, and GABA receptors were blocked withCNQX, AP-5, and bicuculline. However, the depolarization was blockedby atropine, indicating that carbachol depolarizes LM interneuronsby direct activation of muscarinic receptors. Reece and Schwartzkroin(1991a) also found that carbachol depolarized LM cells in an atropine-sensitivemanner that was not blocked by tetrodotoxin. The depolarizationdescribed here was sufficient to induce voltage-dependent oscillationsthat paced cell firing in most of the LM cellssampled.

Ionic mechanisms mediating cholinergic depolarization of LM interneurons are unknown. Carbachol potentiates a low-thresholdCa²⁺ current in LM interneurons, however, this cannot contribute tothe depolarization, because this current is inactivated at restingmembrane potential (Fraser and MacVicar, 1991). Carbachol mayreduce the M-type K⁺ current (I_m) that contributes to cholinergic depolarization ofCA1 pyramidal cells (Halliwell and Adams, 1982; Madison et al.,1987). Carbachol is unlikely to significantly affect K⁺ conductances mediating oscillations in LM cells (Chapman andLacaille, 1999) because the power and frequency of oscillationsinduced in carbachol did not differ from those induced with positivecurrent injection in normal ACSF. Increased input resistance,observed in some LM cells, would be consistent with attenuationof K⁺ conductances by carbachol, but carbachol also depolarized cellsin which there was no change or a decrease in input resistance(see also Reece and Schwartzkroin, 1991a). In stellate cells ofthe entorhinal cortex, muscarinic depolarization is mediated byactivation of a Ca²⁺-dependent cationic conductance; an effect that is also associatedwith minimal changes in input resistance (Klink and Alonso, 1997a,b).

A transient hyperpolarization after carbachol application preceded the depolarizing response in some cells. Nicotinic receptorsare unlikely to contribute because nicotinic activation resultsin fast inward currents in LM interneurons (Jones and Yakel, 1997;Frazier et al., 1998; McQuiston and Madison, 1999; see Reece andSchwartzkroin, 1991b), and hyperpolarization of LM cells was notobserved in atropine (Fig. 3). Direct muscarinic hyperpolarizationof interneurons has been observed in cortex (Xiang et al., 1998),and similar mechanisms could occur in LM cells. Alternatively,muscarinic activation of other inhibitory cells (Pitler and Alger,1992; Behrends and ten Bruggencate, 1993) could contribute tothe transient hyperpolarization of LM interneurons, because inhibitoryinputs originating from other interneurons (Misgeld and Frotscher,1986; Williams et al., 1994; Khazipov et al., 1995; Atzori, 1996;Hájos and Mody, 1997) may be activated strongly by carbacholapplication (McMahon et al., 1998). Hyperpolarizations occurredin both normal ACSF and in the presence of bicuculline (Fig. 2),indicating that GABA_A receptor activation was not required. However,intense activation of interneurons during carbachol application(McMahon et al., 1998) may be sufficient for activation of GABA_Bsynapticinhibition.

Minimal stimulation

The effects of minimal stimulation demonstrated that single fiber IPSPs from interneurons activated in stratum lacunosum-molecularecan have powerful effects on firing properties of CA1 pyramidalcells. Similar to results reported previously for basket and axoaxoniccells (Cobb et al., 1995), minimal stimulation in stratum lacunosum-moleculareevoked IPSPs that resulted in rebound action potentials in pyramidalcells. In contrast to basket and axoaxonic cells that provideinhibition to the soma and initial segment pyramidal cells (Halasyet al., 1996), axons of LM cells arborize primarily in apicaldendritic fields (Kunkel et al., 1988) and mediate a more slowlydecaying inhibition (Ouardouz and Lacaille, 1997; Banks et al.,1998). It is shown here that dendritic inhibition generated byinterneurons activated in stratum lacunosum-moleculare is alsoeffective in inducing rebound depolarization and spiking in pyramidalcells (see also Lacaille and Schwartzkroin, 1988b, their Fig.4A).

When low-frequency minimal stimulation was used to mimic rhythmic inhibition generated by LM interneurons, the repetitivespiking of pyramidal cells was set to ~180° out of phase withthe activation of interneurons by minimal stimulation. Intrinsicconductances generate theta-frequency membrane potential oscillationsin pyramidal cells (Nuñez et al., 1987; Leung and Yim, 1991;Garcia-Munoz et al., 1993; Cobb et al., 1995), and IPSPs generatedby activation of basket and axoaxonic cells can pace and synchronizethese oscillations (Cobb et al., 1995). It is shown here thatthe dendritic inhibition activated by interneurons in stratumlacunosum-moleculare can also pace oscillations at theta-frequencyin pyramidal cells. Furthermore, because membrane potential ofLM cells oscillates at theta-frequency in response to depolarization,and IPSPs generated by LM cells decay with a time constant ofapproximately one-half of the duration of the theta cycle, thisinterneuronal subtype may play a more specialized role in thepacing of theta activity than other interneurontypes.

Functional relevance to theta activity

Inhibitory circuits of the hippocampus contribute significantly to theta-frequency activity in pyramidal neurons (Leung, 1984;Fox, 1989; Cobb et al., 1995; Ylinen et al., 1995; Tóth et al.,1997). Cholinergic depolarization of LM cells leading to intrinsictheta-frequency oscillations and rhythmic inhibition of pyramidalneurons may be a significant mechanism through which the medialseptum contributes to the generation of hippocampal theta activity.This role for LM cells differs markedly from the role of otherinterneuronal subtypes in which tonic firing is thought to bereduced during theta by GABAergic septal afferents (Bland andColom, 1993; Bland et al., 1999) and in which phasic septal inhibitionmay result in phasic disinhibition of pyramidal cells (Tóth etal., 1997). Furthermore, because LM interneurons primarily inhibitdendrites rather than the soma of pyramidal cells, they can providedendritic inhibition that can effectively modulate dendritic depolarizationmediated by direct entorhinal cortex inputs to the CA1 region(Witter et al., 1988; Kamondi et al., 1998). LM cells may alsoeffectively modify levels of dendritic excitability that governthe phase-dependent induction of long-term synaptic potentiationor depression during cholinergically induced oscillations (Huertaand Lisman, 1995).

To provide rhythmic theta-frequency inhibition of large populations of pyramidal cells, the activity of multiple LM interneuronsmust be closely phase-related. Theta-frequency activity may besynchronized in multiple LM cells through a number of mechanismsincluding feedforward inputs from CA3 pyramidal cells and thecontralateral CA1 region (Kunkel et al., 1988), mutual inhibitionamong interneurons (Atzori, 1996), and afferents from the entorhinalcortex (Kunkel et al., 1988). A most significant factor, however,is likely to be phasic inputs from medial septal GABAergic inhibitoryinputs (Freund and Antal, 1988; Gulyás et al., 1990).

In conclusion, the results presented here strongly suggest that septal cholinergic efferents contribute to theta activityin the CA1 region in part by causing muscarinic depolarizationof LM interneurons and inducing theta-frequency firing in LM cellscaused by activation of intrinsic membrane potential oscillations(Chapman and Lacaille, 1999). The resulting rhythmic inhibitiongenerated by LM cells can cause rebound action potentials in pyramidalcells and set the phase of intrinsic theta-frequency oscillationsin pyramidal cells. Cholinergic induction of theta-frequency oscillationsin LM interneurons leading to rhythmic inhibition of pyramidalcells may therefore be an important mechanism through which themedial septum modulates and paces hippocampal theta activity invivo.

  FOOTNOTES

Received May 11, 1999; revised June 18, 1999; accepted June 20, 1999.

This research was funded by a grant to J-C.L. from the Medical Research Council of Canada (MT-10848). J-C.L. is a senior scholarof the Fonds de la Recherche en Santé du Québec (FRSQ), a memberof the Groupe de Recherche sur la Système Nerveux Central [Fondspour la Formation de Chercheurs et l'aide à la Recherche (FCAR)],and a member of an Equipe de recherche from FCAR. C.A.C. was supportedby postdoctoral fellowships from the Natural Sciences and EngineeringResearch Council of Canada and theFRSQ.
Correspondence should be addressed to Dr. Lacaille, Département de Physiologie, Faculté de Médecine, Université de Montréal,C.P. 6128 Succ. Centreville, Montréal, Québec, H3C 3J7Canada.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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