Synaptic Interactions of Late-Spiking Neocortical Neurons in Layer 1

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The Journal of Neuroscience, January 1, 2003, 23(1):96-102

Synaptic Interactions of Late-Spiking Neocortical Neurons in Layer 1
Zhiguo Chu¹, Mario Galarreta¹, and Shaul Hestrin¹^,²
Departments of ¹ Comparative Medicine and ² Neurology and Neurological Sciences, Stanford University School of Medicine, Stanford, California 94305-5342

  ABSTRACT

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Layer 1 of the neocortex is an important zone in which synaptic integration of inputs originating from a variety of cerebralregions is thought to take place. Layer 1 does not contain pyramidalcells, and several histochemical studies have suggested that mostlayer 1 neurons are GABAergic. However, although layer 1 neuronscould be an important source of inhibition in this layer, thesynaptic action of these neurons and the identity of their postsynaptictargets are unknown. We studied the physiological properties andsynaptic interactions of a class of cells within layer 1 calledlate-spiking (LS) cells. The dendrites and axons of layer 1 LScells were confined primarily to layer 1. Using paired recording,we showed that LS cells formed GABAergic connections with otherLS cells as well as with non-LS cells in layer 1 and with pyramidalcells in layer 2/3. We also found that layer 2/3 pyramidal neuronsprovide excitatory inputs to LS cells. It has been suggested previouslythat GABAergic neurons belonging to the same class in the cortexare electrically coupled. In agreement with that hypothesis, wefound that LS cells were interconnected by electrical coupling(83%), whereas electrical coupling between LS cells and non-LScells was infrequent (2%). Thus, we provide evidence showing thata group of GABAergic neurons within layer 1 are specifically interconnectedby electrical coupling and can provide significant inhibitoryinputs to neurons in layer 1 and to distal dendrites of pyramidalcells.

Key words: neocortex; layer 1; inhibition; electrical coupling; late-spiking cells; neurogliaform cells

  Introduction

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Layer 1 is a unique layer in the neocortex because it lacks pyramidal neurons. Layer 1 contains axons originating from pyramidaland nonpyramidal neurons located in layers 2-6 and also from otherregions (Vogt, 1991), including feedback projections from highercortical areas (Felleman and Van Essen, 1991) and thalamocorticalaxons from specific and nonspecific thalamic nuclei (Mitchelland Cauller, 2001; Llinas et al., 2002). Thus, it has been suggestedthat layer 1 integrates inputs from high-order cortical and thalamicareas (Cauller and Kulics, 1991; Mitchell and Cauller, 2001; Llinaset al., 2002).

The axons in layer 1 are predominantly glutamatergic and GABAergic but also include cholinergic, noradrenergic, and serotoninergicaxons (Vogt, 1991), and their main targets are the apical dendritictufts of pyramidal cells in layers 2-6. In addition to projectinginput axons and dendrites of layers 2-6 neurons, layer 1 alsocontains nonpyramidal neurons (DeFelipe and Jones, 1988). Themorphological appearance of layer 1 neurons and the presence ofGABAergic markers suggest that they are inhibitory cells (Gabbottand Somogyi, 1986; DeFelipe and Jones, 1988; Winer and Larue,1989; Li and Schwark, 1994; Hestrin and Armstrong, 1996; Zhouand Hablitz, 1996a). Thus far, however, the inhibitory actionof layer 1 neurons has not been demonstrated, and their postsynaptictargets have not been identified. Inhibition in layer 1 couldbe highly effective in governing the excitatory synaptic inputin this layer. Thus, it is important to determine directly thesynaptic action of layer 1 neurons on their postsynaptic targetneurons. Given that extracellular stimulation methods cannot beused to identify the presynaptic cells, we recorded from pairsof neurons consisting of a layer 1 cell together with either otherlayer 1 neurons or layer 2/3 pyramidalcells.

  Materials and Methods

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Slice preparation. Neocortical slices were obtained from Sprague Dawley rats (14-24 d old). Briefly, rats were anesthetizedwith ketamine (87 mg/kg) and xylazine (13 mg/kg) and decapitated.The brain was quickly removed and placed in ice-cold (0-4°C) extracellularsolution containing the following (in mM): 125 NaCl, 2.5 KCl,1.25 NaH₂PO₄, 1.0 MgSO₄, 2.0 CaCl₂, 26 NaHCO₃, 20 D-glucose, 0.4ascorbic acid, 2.0 pyruvic acid, and 4.0 lactic acid. The pH wasmaintained by continuous bubbling with a gas consisting of 95%O₂ and 5% CO₂. The brain was hemisected, and a block of cortexwas glued to the stage of a Vibratome (VT1000S; Leica, Heidelberg,Germany). Parasagittal cortical slices (300 µm thick, 30° angle)were cut, transferred to a holding chamber, and incubated at atemperature of 32-34°C for 30 min. The slices were maintainedat room temperature until they were transferred to the recordingchamber. The recording chamber was mounted on the stage of anupright microscope (Axioskop FS-1; Zeiss, Thornwood, NY) equippedwith a 40× water immersionobjective.

Cell identification. Nonpyramidal neurons in layer 1 of the visual and somatosensory cortices were selected and identifiedon the basis of their electrophysiological and morphological propertiesas detailed below and in Results. Pyramidal neurons in layer 2/3were identified by their somatic shape, apical dendrite, and patternof spiking. We used infrared differential interference contrast(DIC) optics to visualize individual neurons. To distinguish celltypes in layer 1, their responses to near-threshold current injectionwere examined. Layer 1 late-spiking (LS) neurons were distinguishedfrom other types of layer 1 neurons by electrophysiological criteria(see Results). Other neurons in layer 1 lacking these characteristicswere classified as non-LS neurons. Initially, random recordingswithout visual selection were made in layer 1. Under these conditions,39% of the neurons (31 in 79 neurons) were identified as LS neurons.In later studies, neurons with a relatively round soma or multipolarappearance in the middle part of layer 1 were preselected visuallyas putative LS cells. Their identity was later confirmed on thebasis of their electrophysiologicalproperties.

Whole-cell recordings. We recorded from layer 1 neurons and from pyramidal neurons using somatic whole-cell patch-clamp recordings.Patch pipettes were pulled from thin-walled borosilicate glass(outer diameter, 1.5 mm; inner diameter, 1.17 mm; Warner Instruments,Hamden, CT) using a P-87 pipette puller (Sutter Instruments, Novato,CA). Recording pipettes were filled with low-chloride solution[in mM: 140 K-methylsulfate, 6.3 KCl, 10 HEPES, 0.2 EGTA, 4.0MgATP, 0.3 GTP, and 20 phosphocreatine (Na)] or high-chloridesolution [in mM: 106.3 K-methylsulfate, 40 KCl, 10 HEPES, 0.2EGTA, 4.0 MgATP, 0.3 GTP, and 20 phosphocreatine (Na)]. pH wasadjusted to 7.3 and 290 mOsm. Pipettes had resistances of 3-4M $Omega$ . Current- and voltage-clamp recordings were performed usingAxopatch-200B amplifiers (Axon Instruments, Union City, CA). Currentand voltage signals were low-pass filtered at 5 kHz and digitizedat 16 bit resolution (ITC-18; Instrutech, Port Washington, NY)and a sampling frequency of 10 kHz. The liquid junction potentialerror was not corrected. In some experiments, DNQX (20 µM; ResearchBiochemicals, Natick, MA) was present in the bath to block AMPA/kainatereceptor-mediated synaptic currents. The GABA_A receptor antagonist( $-$ )bicuculline methiodide (10-20 µM; Sigma, St. Louis, MO) wasbath applied. All recordings were made at a temperature of 33-34°C.

Data analysis. Data acquisition and data analysis were done using Igor software (WaveMetrics, Lake Oswego, OR). The inputresistance and membrane time constant of layer 1 neurons weredetermined from the average response to a depolarizing pulse (~5mV, 400-600 msec, 20-50 pA). Spike amplitude and the afterhyperpolarizationpotential (AHP) amplitude were measured relative to the spikethreshold. The time interval between the peak of the action potentialand the minimum of the AHP was measured in traces containing asingle spike. Spike frequency adaptation was measured as the ratioof the third to the first interspike interval (ISI) in tracescontaining four to five spikes. To identify chemical synaptictransmission, action potentials were generated in the presynapticneurons using brief pulses (2-3 msec) of suprathreshold currentsat a frequency of 0.25-0.166 Hz. In the presence of electricalcoupling, a GABAergic connection or its absence was detected bycomparing the postsynaptic responses obtained at membrane potentialsof $-$ 50 and $-$ 90 mV (in low internal chloride). The step couplingcoefficient was calculated as the ratio of the voltage changein the noninjected cell to that in the injected cell. The couplingcoefficient of the spikelet was calculated as the ratio of theaction potential amplitude (using the threshold as reference)and the spikelet amplitude (using the baseline as reference).The junctional conductance between electrically coupled LS cellswas estimated from G_j = (1/R₂) × CC/(1 $-$ CC), where CC is couplingcoefficient and R₂ is input resistance of the noninjected cell.Unless otherwise stated, data are presented as mean ±SEM.

Histology. To study the morphology of layer 1 neurons, 0.5% biocytin was included in the pipette solution. The slices containingbiocytin-filled cells were fixed with 4% paraformaldehyde. Standardavidin-biotinylated-horseradish peroxidase complex (ABC; VectorLaboratories, Burlingame, CA) and the 3,3'-diaminobenzidine reactionprocedure were used. Neurolucida (MicroBrightField, Williston,VT) was used for reconstruction of layer 1 neurons. To study parvalbuminimmunostaining, the slices were fixed overnight and then washedwith PBS solution. Subsequently, they were incubated in a solutioncontaining 1% Triton X-100, 2% normal goat serum, and 2% BSA for4 hr, followed by overnight incubation with rabbit anti-parvalbumin(1:3000; pv28; Swant, Bellinzona, Switzerland). Afterward, theslices were washed with PBS and incubated with Alexa-555 goatanti-rabbit IgG (1:300; A-21428; Molecular Probes, Eugene, OR)for 3 hr. The immunoreactive cells were examined under appropriatefilter systems (Zeiss).

  Results

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Late-spiking cells in layer 1

In contrast to other cortical layers containing both pyramidal and nonpyramidal neurons, layer 1 contains only nonpyramidalcells. Layer 1 neurons are a heterogeneous group and include neuronswhose axons project vertically outside of layer 1 and neuronswhose axons are restricted primarily to layer 1 (DeFelipe andJones, 1988; Hestrin and Armstrong, 1996; Zhou and Hablitz, 1996a).We identified a group of neurons within layer 1 on the basis oftheir electrophysiological responses to current injection. Wecalled these neurons LS cells because their properties were similarto those reported previously for layers 2-6 LS cells (Kawaguchi,1995; Kawaguchi and Kubota, 1997). LS cells were characterizedby the following properties. When we injected prolonged near-thresholdcurrent pulses (600 msec), layer 1 LS cells typically generateda ramp, followed by a delayed spike (Fig. 1A,C). Suprathresholdcurrent injection produced discharges of nonadapting spikes (thirdISI/first ISI = 1.1 ± 0.01; n = 207). After an action potential,during the injection of a prolonged current pulse, LS cells exhibiteda single-component fast AHP (Fig. 1A, arrow). The minimum of theAHP of LS cells occurred at <10 msec intervals after the actionpotential peak (average, 4.9 ± 0.1 msec; n = 207). In addition,LS cells displayed a depolarizing waveform after spikes generatedby injection of a brief current pulse, called an afterdepolarization(Fig. 1D) (Hestrin and Armstrong, 1996; Zhou and Hablitz, 1996b;Budde and White, 1998). Neurons not showing these characteristicswere heterogeneous and were called collectively non-LS cells (Fig.1B). Non-LS cells had slower AHP (19.3 ± 0.7 msec; n = 154) thanLS cells (Fig. 1B). In addition, non-LS cells exhibited spikefrequency adaptation during prolonged current injection (Fig.1B) (third ISI/first ISI = 1.9 ± 0.17; n = 154).

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Figure 1. Electrophysiological properties of LS cells in layer 1. A, Top, DIC-infrared video microscopy image of an LS cell. Scale bar, 10 µm. Bottom, Firing pattern of the same cell in response to the injection of depolarizing current pulses. The two top traces were produced with the same magnitude of current injection. Note the delayed firing during the current injection, the single-component fast AHP (arrow), and the lack of spike frequency adaptation in the near-threshold discharge (middle trace). Resting V_m, $-$ 62 mV. B, DIC-infrared video microscopy image (top) and pattern of firing in response to current injection (bottom) of a non-LS cell. Resting V_m, $-$ 81 mV. Calibration as in A. C, Current-clamp recording from an LS cell in response to two near-threshold current injections. Note the slow depolarizing ramp commonly observed in LS cells under these conditions. An action potential was produced at the end of the pulse in one of the traces. Resting V_m, $-$ 69 mV. D, Recording from an LS cell. A single action potential induced by a brief current injection (300 pA, 5 msec) was followed by an afterdepolarization (ADP). The action potential has been truncated. Resting V_m, $-$ 72 mV.

We found that the average input resistance of LS cells was 245.9 ± 5.5 M $Omega$ (n = 163), and their membrane time constant was19.9 ± 1.1 msec (n = 78). In addition, the average frequency ofthe near-threshold discharges of LS cells was 16.1 Hz (n = 160).This value is smaller than that reported previously for fast-spiking(FS) cells in lower cortical layers, which is typically >50 Hz(Galarreta and Hestrin, 1999). In addition, FS cells in layers2-6 express the calcium-binding protein parvalbumin (Kawaguchiand Kubota, 1997), but layer 1 neurons are parvalbumin immunonegative(data not shown). Thus, LS cells in layer 1 represent a differentclass than FScells.

Morphology of LS cells

LS and non-LS cells were filled with biocytin during the recording to reconstruct their structure (Fig. 2) (LS, n = 6; non-LS,n = 4). We found that cells identified on the basis of electrophysiologicalcharacteristics as LS cells had a dense local axon extending horizontally(Fig. 2,A1-A3). The somata of LS cells were multipolar, and theirdendrites were radial, short, and aspinous. Both dendrites andaxons of LS cells were included primarily in layer 1. This morphologyis similar to that described previously for neurogliaform cellsin layer 1 (DeFelipe and Jones, 1988; Anderson et al., 1992; Hestrinand Armstrong, 1996). In other cortical layers, LS cells havebeen shown to include neurogliaform cells (Kawaguchi, 1995; Kawaguchiand Kubota, 1997). Non-LS cells had a heterogeneous morphologicalappearance. In general, the axon belonging to the non-LS cellswas diffuse, projecting in both layer 1 and the lower layers (Fig.2B).

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Figure 2. Morphology of nonpyramidal cells in layer 1. A, Neurolucida reconstruction of three LS cells (A₁-A₃) filled with biocytin. Dendrites are illustrated with thick traces, and axons are illustrated with thin traces. Note the extensive axonal arborizations distributed around the soma and extending horizontally within layer 1. Insets, Pattern of firing of the reconstructed neurons in response to near-threshold current injections. B, Neurolucida reconstruction of a non-LS cell. The axon, whose origin is indicated by the arrowhead, extends into lower layers of the neocortex. Inset, Pattern of firing in response to a depolarizing current injection.

Synaptic connections between LS cells and pyramidal neurons

Neurons in layer 1 express GABAergic markers, suggesting that they are inhibitory interneurons (Gabbott and Somogyi, 1986;Beaulieu et al., 1992; Li and Schwark, 1994). However, no directconfirmation of the inhibitory function by layer 1 neurons hasbeen demonstrated. To test the synaptic function by LS layer 1neurons at pyramidal cells, we recorded from pairs consistingof a presynaptic LS cell and a layer 2/3 pyramidal neuron (Fig.3A) (10 connected pairs, 142 pairs tested; intersomata distance,75-180 µm). As illustrated in Figure 3, at a postsynaptic membranepotential of $-$ 48 mV, a presynaptic action potential produced ahyperpolarizing IPSP (n = 5). When the membrane potential waskept at $-$ 93 mV, the postsynaptic response was depolarizing (lowinternal chloride). These results show that LS cells are inhibitoryneurons and suggest that the postsynaptic response could reflectan increase to chloride conductance. At connections between apresynaptic LS cell and layer 2/3 pyramidal neurons, the averagerise time (10-90%) of the IPSPs was 12.6 ± 7.0 msec (n = 10).The IPSPs were fit with an exponential function, and the timeconstant was 27.2 ± 11.1 msec (mean ± SD; n = 3) using low chlorideinternal solution at depolarizing potentials ( $-$ 45 to $-$ 55 mV) and27.7 ± 6.6 msec (mean ± SD; n = 4) using high internal chlorideat approximately $-$ 90 mV. Thus, these data suggest that LS cellsof layer 1 make chloride-dependent inhibitory synaptic inputsat their pyramidal cells targets.

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Figure 3. Synaptic connectivity between layer 1 LS neurons and layer 2/3 pyramidal (Pyr) cells. A, Paired recording between a presynaptic LS cell in layer 1 (Pre) and a postsynaptic pyramidal cell in layer 2/3 (Post). Top, Schematic drawing of the pair. Top trace, Presynaptic action potential induced by a brief current injection. Middle trace, Unitary IPSP recorded at a V_m of $-$ 48 mV. Dotted line, Single-exponential fit ( $tau$ = 36.3 msec). Bottom trace, unitary IPSP recorded at a V_m of $-$ 93 mV (low internal chloride). Note that the unitary IPSP reversed its polarity and became depolarizing. The capacitative surge in the postsynaptic cell was blanked. B, Paired recording between a presynaptic layer 2/3 pyramidal neuron (bottom trace, Pre) and a postsynaptic layer 1 LS cell. Top, Schematic drawing of the pair. Top trace, Unitary EPSP recorded at a V_m of $-$ 60 mV. C-Clamp, Current clamp; V-Clamp, voltage clamp. Dotted line, Single-exponential fit ( $tau$ = 7.1 msec). Middle trace, Unitary EPSC recorded under voltage-clamp mode (holding potential, $-$ 45 mV). Traces in A and B are the average of >100 trials (stimulation frequency, 0.25 Hz).

It has been shown previously that layer 1 neurons receive excitatory synaptic inputs (Hestrin and Armstrong, 1996; Zhou andHablitz, 1997). One possible source of these excitatory inputsto layer 1 neurons could originate from layer 2/3 pyramidal neuronswhose axons send collateral branches into layer 1. In agreementwith that suggestion, we found that LS cells receive EPSPs frompresynaptic layer 2/3 pyramidal cells (Fig. 3B). At connectionsbetween a presynaptic layer 2/3 pyramidal cell and a postsynapticLS cell, the average rise time (10-90%) of the EPSPs was 2.6 ±1.6 msec (n = 3), and the average EPSP decay time constant was10.0 ± 2.1 msec (mean ± SD; n = 3 connected pairs; 101 pairs tested).Figure 3B illustrates an EPSP at the pyramidal cell-to-LS connectionthat had an exponential time constant of 7.1 msec. Under voltageclamp at a holding potential of $-$ 45 mV, the EPSC of this connectionhad a decay time constant of 3.2 msec (Fig. 3B).

Synaptic connections between LS cells and non-LS cells

In addition to dendrites of pyramidal cells from lower layers, LS cells could also target both other LS cells and non-LS cellsin layer 1. We found that LS cells provide inhibitory inputs tonon-LS cells in layer 1 (n = 19 pairs connected; 107 pairs tested)(Fig. 4A). The synaptic inputs were hyperpolarizing when recordedwith low-chloride-containing pipettes at a depolarized membranepotential (Fig. 4A) (n = 4). When we used high-chloride-containingpipettes, the response was reversed, and the IPSPs were depolarizingat membrane potentials of $-$ 60 to $-$ 45 mV (Fig. 4B). The IPSPs ofLS-to-non-LS connections were slow, the average decay time constantwas 31.2 ± 3.6 msec (n = 14), and the rise time was 10.6 ± 1.0msec (n = 17). Furthermore, we also found that non-LS cells madeinhibitory connections with layer 1 LS cells (n = 2 pairs) andlayer 2/3 pyramidal cells (n = 4 pairs) and receive excitatoryconnections from layer 2/3 pyramidal cells (n = 2 pairs).

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Figure 4. LS cells make inhibitory GABAergic chemical synapses to other interneurons in layer 1. A, B, Paired recordings from two pairs consisting of a presynaptic LS cell (Pre) and a postsynaptic non-LS cell (Post) in layer 1. A, A hyperpolarizing unitary IPSP was recorded when the postsynaptic cell was kept at a V_m of $-$ 54 mV and a low-chloride internal solution was used (E_Cl of $-$ 76 mV). B, The polarity of the unitary IPSP changed when the postsynaptic cell was filled with a high-chloride internal solution (E_Cl of $-$ 30 mV).

Electrical coupling and inhibitory connections among LS cells

We studied the synaptic interactions among LS cells in layer 1. It has been suggested that, in the cortex, GABAergic cellsbelonging to the same class are interconnected via electricalcoupling (Galarreta and Hestrin, 1999, 2001b; Gibson et al., 1999).To test whether this notion applies to LS cells in layer 1, werecorded from pairs of LS cells. We found that 83% of LS cellpairs were electrically coupled (n = 49 coupled; 59 pairs tested)and that 26.2% of the LS cell pairs were chemically connected(n = 17 pairs connected; 65 pairs tested). When both electricaland chemical connections were present, we found a dual-componentpostsynaptic response exhibiting a depolarizing phase, followedby a hyperpolarizing phase (V_m = $-$ 50 mV) (Fig. 5A). When high-chloride-containingpipettes were used, the IPSP was depolarizing (Fig. 5B) (n = 9;33 pairs tested). These data indicate that LS cells are interconnectedby inhibitory synapses. In addition, in four experiments, we foundthat bicuculline (20 µM) blocked the IPSP (Fig. 5C). The IPSPat LS-to-LS connections was slow; the decay time constant was46.7 ± 3.8 msec (n = 14).

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Figure 5. Paired recording between a pair of LS cells connected via both electrical and chemical synapses. A, At a V_m of $-$ 50 mV, the postsynaptic potential (bottom traces, Post) was biphasic, with a depolarizing component mediated by the electrical connection and a hyperpolarizing component reflecting the IPSP. When the postsynaptic response was recorded at $-$ 92 mV, the unitary IPSP was reduced dramatically, whereas the electrically mediated depolarization remained unmodified (low-chloride internal postsynaptic solution). Top trace, Presynaptic action potential (Pre) in response to a brief depolarizing current injection. B, Paired recording from a different pair of LS cells connected by electrical and chemical synapses. A depolarizing unitary IPSP was recorded when the postsynaptic cell was kept at a V_m of $-$ 59 mV and a high-chloride internal solution was used. C, Paired recording from a pair of LS cells connected only chemically. The depolarizing IPSP recorded at a V_m of $-$ 91 mV (Control) was blocked in the presence of bicuculline (BIC) at 20 µM (high-chloride internal solution). Traces in A are the average of 100 trials. Traces in B and C are the average of 16-24 trials. The coupling coefficient of the pair shown in A was 14%, and that shown in B was 8.3%. The pair shown in C was not electrically coupled.

To study the electrical coupling among LS cells in isolation, we recorded from pairs of LS cells (Fig. 6A). Under current-clampconditions, we injected long steps of either hyperpolarizing ordepolarizing currents in one cell. As shown in Figure 6B, thenoninjected cells reflected the response of the injected cell.The electrical coupling that we found among LS cells was bidirectionalat the range of membrane potential that we studied. The averagecoupling coefficient of pairs of LS cells was 4.5 ± 0.8% (range,0.53-16.9%; n = 31).

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Figure 6. Electrical coupling among layer 1 LS neurons. A, Neurolucida reconstruction of a pair of LS cells in layer 1. Dendrites are illustrated with thick traces, and axons are illustrated with thin traces. Left, Photograph illustrating the same pair of cells filled with biocytin. Scale bar (in photomicrograph), 10 µm. Top insets, Firing pattern of the two LS cells in response to a pulse of depolarizing current. B, Left, Injecting a pulse of depolarizing or hyperpolarizing current in LS₁ affected the membrane of both LS₁ and LS₂. Similarly, injecting current in LS₂ depolarized or hyperpolarized the membrane of LS₁ (right). Data from the pair of cells shown in A. Step coupling coefficients were as follows: 6.65% in LS₁-to-LS₂ and 8.1% in LS₂-to-LS₁. Traces are the average of >130 trials.

To test for the specificity of the electrical coupling, we recorded from pairs consisting of an LS cell and a non-LS cell(Fig. 7A,B). Of 93 pairs tested, only two LS-to-non-LS pairs wereelectrically coupled. Overall, we found that the frequency ofelectrical coupling among LS-to-LS pairs was 83% (Fig. 7C) (49of 59), whereas the probability of electrical coupling at LS-to-non-LSpairs was only 2% (2 of 93). These results indicate that electricalcoupling is highly specific, as has been found in other layersof the neocortex (Galarreta and Hestrin, 2001b).

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Figure 7. Electrical coupling among nonpyramidal cells in layer 1 is cell type specific. A, Photograph of an LS cell and a non-LS (nLS) cell simultaneously recorded in layer 1. Scale bar (in photomicrograph), 10 µm. The insets show their distinct patterns of firing in response to current injection. B, Injecting a pulse of depolarizing current in the LS (left) or the non-LS cell (right) did not affect the membrane potential of the noninjected cell. C, Histogram illustrating the percentage of pairs electrically coupled. Note the high rate of electrical coupling among LS cells (83%; 49 of 59 pairs) in contrast with the very low rate among the pairs consisting of an LS and a non-LS cell (2%; 2 of 93 pairs).

The properties of electrical coupling

We compared the coupling coefficients at each LS-to-LS pair by injecting current to cell 1 or cell 2 (Fig. 8A). The estimatedbidirectional coupling coefficients were similar, suggesting thatthe electrical junctions were located at similar electrotonicdistances from the somata. We found that the magnitude of thecoupling coefficient seems to depend on the distance between theLS cell somata. When the distance was <40 µm, the range was higherthan that measured when the distance was 40-120 µm (Fig. 8B).The average coupling conductance (see Materials and Methods) was178.8 ± 31.5 pS (n = 31 pairs; range, 32.6-642.6 pS).

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Figure 8. Properties of electrical coupling among layer 1 LS cells. A, Electrical coupling was bidirectional. Comparison of step coupling coefficient when current was injected in LS₁ versus LS₂. B, Step coupling coefficient as a function of the distance between the somata of the two electrically coupled LS cells (n = 31 pairs). C, Example of spike transmission in a pair of LS neurons that were connected only via electrical synapses (see Materials and Methods). A prolonged depolarization of the presynaptic cell produced spontaneous action potentials that were transmitted to a postsynaptic neuron as a brief depolarization, followed by a slow hyperpolarization. The holding potential of postsynaptic cell was $-$ 75 mV. Traces were aligned to the peak of the presynaptic spike and represent the average of 102 trials. The step coupling coefficient was 16.9%, and the spike coupling coefficient was 1.4%. D, Superimposition of the presynaptic spike and the corresponding response in the coupled postsynaptic neuron. The latency between the peak of presynaptic spike (Pre) and the peak of the spikelet or postsynaptic response (Post) was 0.7 msec. Data from the same pair as in C.

In addition to transmission of low-frequency signals among coupled cells, presynaptic spikes could also affect an electricallycoupled cell. To record spikelets, we selected LS-to-LS pairsthat did not have GABAergic connections (see Materials and Methods).The "presynaptic" cell was depolarized by injection of steadycurrent-producing spikes. We used these spikes to obtain the spike-triggeredaverage of the "postsynaptic" response (Fig. 8C). Under theseconditions, the spikelet had a fast depolarizing phase, followedby a larger hyperpolarizing phase reflecting the presynaptic spikeAHP. The ratio of the presynaptic spike to the spikelet amplitudewas 0.47 ± 0.07% (n = 28), and the spikelet latency was 1.0 ±0.1 msec (n =28).

  Discussion

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

In this report, we directly demonstrated that layer 1 neurons of the LS cell class provide inhibitory inputs to pyramidalcells and to layer 1 neurons. Furthermore, we found that LS cellsare specifically and highly interconnected by electrical coupling.In addition, we showed that LS cells receive excitatory inputsfrom layer 2/3 pyramidalneurons.

Late-spiking cells in layer 1

Although layer 1 is sometimes described as an acellular layer, it was shown by Cajal that layer 1 contains interneurons (DeFelipeand Jones, 1988). Furthermore, Cajal recognized that the layer1 neurons are heterogeneous. More recent studies revealed thatlayer 1 neurons express GABAergic markers and that the densityof GABAergic neurons in layer 1 is ~50% of that found in layers2-6 (Gabbott and Somogyi, 1986; Winer and Larue, 1989; Li andSchwark, 1994). Cajal identified previously neurogliaform cellsin layer 1 (DeFelipe and Jones, 1988), and, more recently, Martinet al. (1989) recorded visual responses from a layer 1 neuronthat morphologically resembles a neurogliaform cell. In this study,we characterized late-spiking cells in layer 1 that have multipolarsomata, short dendrites, and a dense local axonal projection thatgenerally remained within layer 1 extending horizontally. Theelectrophysiological properties of layer 1 LS cells suggest thatthese cells may be similar to neurogliaform cells in layers 2-6(Jones, 1984; Kawaguchi, 1995; Kawaguchi and Kubota, 1997).

Inhibitory and excitatory synapses of LS cells

It was shown previously that layer 1 neurons express GABAergic markers (Gabbott and Somogyi, 1986; Winer and Larue, 1989;Beaulieu et al., 1992; Li and Schwark, 1994). In addition, recentstudies showed that extracellular stimulation in layer 1, whichmay activate layer 1 neurons, could produce inhibition at pyramidalcells (Helmchen et al., 1999; Larkum and Zhu, 2002). Nonetheless,the synaptic action of layer 1 neurons and the identity of theirtargets remain unknown. The paired-recording data presented heredemonstrate directly that LS neurons in layer 1 are indeed inhibitoryat several targets, including layer 1 interneurons and pyramidalcells.

Presynaptic action potentials in LS cells produced hyperpolarizing responses when the membrane potential of the postsynapticcell was $-$ 50 to $-$ 60 mV. These IPSPs were depolarizing when highinternal chloride was used, and they were blocked by bicuculline.Thus, these data show that the IPSPs generated by LS cells aremediated by GABA_A receptors. The rise time and decay time constantsof the IPSPs were slow compared with IPSPs generated by FS cells(Geiger et al., 1997; Galarreta and Hestrin, 1999, 2001a; Gibsonet al., 1999). Given that the axonal projections of LS cells wereconfined primarily to layer 1, it is likely that the synapticcontact of LS and pyramidal cells occurs at distal dendrites,which may produce slow synaptic response. However, it is alsopossible that the GABA_A receptors mediating the IPSPs of LS cellsare slow compared with the GABA_A receptors mediating inhibitionby FS cells. Connections between LS cells and either LS cellsor other layer 1 neurons may also have occurred at dendrites,but anatomic investigation is necessary to determine the synapticlocation.

We found that local pyramidal neurons provide excitatory inputs to LS cells. The time course of the EPSCs and EPSPs at pyramidal-to-LScells is fast (Fig. 3B), suggesting that these synapses are somaticor proximal. In addition to inputs from local pyramidal cells,LS cells could also receive excitatory inputs from other sources,including thalamic nuclei and other corticalareas.

Electrical coupling

Previous studies suggested that, in the neocortex, electrical coupling may be a specific property of GABAergic neurons andthat only cells belonging to the same class are coupled (Galarretaand Hestrin, 1999; Gibson et al., 1999; Tamas et al., 2000; Szabadicset al., 2001; Meyer et al., 2002) (for review, see Galarreta andHestrin, 2001b). Given that the LS cells in layer 1 are GABAergic,we then asked whether these cells are electrically coupled. Usingpaired recordings, we demonstrated that 83% of LS pairs were electricallycoupled, whereas pairs consisting of an LS cell and a non-LS cellwere only rarely electrically coupled (2%). Thus, our data supportand extend the idea that electrical coupling defines multiplenetworks of GABAergic neurons embedded within theneocortex.

The general properties of the electrical coupling among LS cells, including the coupling strength, are similar to those amongFS and low-threshold spiking (LTS) cells (Galarreta and Hestrin,2001b). It has been shown that the neuron-specific connexin Cx36underlies electrical coupling among FS and LTS cells (Deans etal., 2001; Hormuzdi et al., 2001). Whether Cx36 is expressed inLS cells needs to be determined. We did not observe dye couplingamong layer 1 neurons when we included biocytin in our recordingpipettes (but see Benardo, 1997). Lack of dye coupling among electricallycoupled cells has been observed previously (Gibson et al., 1999)(for review, see Galarreta and Hestrin, 2001b) and may be relatedto the low conductance of individual gap junction channels (Srinivaset al., 1999).

Functional implications

Excitatory inputs at layer 1 include axons originating from specific and nonspecific thalamic nuclei, from other corticalareas, and from layer 2-6 pyramidal neurons. The main targetsof the excitatory fibers in layer 1 are the apical dendritic tuftsof layer 2-6 pyramidal cells. It has been shown that activationof excitatory axons in layer 1 can be very effective in producingdendritic action potentials that propagate anterogradely and influencethe activity of pyramidal cells at all cortical layers (Kim andConnors, 1993; Cauller and Connors, 1994; Zhu, 2000). Given thatthe apical tufts of pyramidal neurons in layer 1 may act as aspike initiation zone (Oakley et al., 2001; Larkum and Zhu, 2002),local inhibition in layer 1 could play an important role in governingthe generation and propagation of action potentials in this zone.The axons of some inhibitory neurons in layers 2-6, includingMartinotti cells, ascend to layer 1, and thus, inhibition at layer1 is likely to depend on several types of inhibitory cells inaddition to the layer 1 LS cells. We showed here that LS cellsreceive excitatory inputs from local pyramidal cells, but it remainsto be determined whether LS cells receive inputs from other excitatoryaxons in layer 1. The high degree of electrical coupling amongLS cells that we demonstrate here suggests that these cells maybe able to synchronize their activity and thus exert powerfulcontrol at their postsynaptic targets. Recently, in vivo experimentshave shown that activation of layer 1 fibers leads to excitation,followed by inhibitory response (Helmchen et al., 1999; Larkumand Zhu, 2002). Our data suggest that LS cells in layer 1 maycontribute to the inhibition observed under physiologicalconditions.

  FOOTNOTES

Received Sept. 4, 2002; revised Oct. 8, 2002; accepted Oct. 15, 2002.

This work was supported by National Institutes of Health Grants EY-12114 and EY-09120. We thank Veronika Zsiros for helpfuldiscussions and Rachel Hestrin and Jane Li for Neurolucidareconstructions.

Correspondence should be addressed to Dr. Shaul Hestrin, Department of Comparative Medicine, Stanford University School ofMedicine, 300 Pasteur Drive, R314, Stanford, CA 95305-5342. E-mail:shaul.hestrin{at}stanford.edu.

  References

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ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

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