Specific Roles of NMDA and AMPA Receptors in Direction-Selective and Spatial Phase-Selective Responses in Visual Cortex

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The Journal of Neuroscience, March 1, 2001, 21(5):1710-1719

Specific Roles of NMDA and AMPA Receptors in Direction-Selective and Spatial Phase-Selective Responses in Visual Cortex
Casto Rivadulla, Jitendra Sharma, and Mriganka Sur
Department of Brain and Cognitive Sciences, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cells in the superficial layers of primary visual cortex (area 17) are distinguished by feedforward input from thalamic-recipientlayers and by massive recurrent excitatory connections betweenneighboring cells. The connections use glutamate as transmitter,and the postsynaptic cells contain both NMDA and AMPA receptors.The possible role of these receptor types in generating emergentresponses of neurons in the superficial cortical layers is unknown.Here, we show that NMDA and AMPA receptors are both involved inthe generation of direction-selective responses in layer 2/3 cellsof area 17 in cats. NMDA receptors contribute prominently to responsesin the preferred direction, and their contribution to responsesin the nonpreferred direction is reduced significantly by GABAergicinhibition. AMPA receptors decrease spatial phase-selective simplecell responses and generate phase-invariant complex cellresponses.

Key words: cat primary visual cortex; glutamate receptors; cortical networks; emergent responses; feedforward connections; recurrent connections

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The circuitry of the cerebral cortex is marked by anatomical connections between neurons and by neurotransmitter receptorsystems that impart specific functions to these connections. Cellsin layer 4 of the adult primary visual cortex, for example, receiveexcitatory input from the lateral geniculate nucleus, from othercortical cells in layer 4, and from cells in layer 6 (Gilbertand Wiesel, 1979). These connections use glutamate as the neurotransmitter,acting primarily on AMPA receptors (Fox et al., 1989; see alsoMiller et al., 1989). In contrast, cells in the superficial layersof the cortex receive excitatory input primarily from layer 4cells and from other layer 2/3 cells. These connections also useglutamate, but the postsynaptic receptors include both AMPA andNMDA receptors (Fox et al., 1989, 1990). In addition, cells inall cortical layers receive inhibitory input, mediated primarilyby GABA (Sillito, 1977; Tsumoto et al., 1979).

Although glutamate is an ubiquitous excitatory neurotransmitter in the cortex, the specific function of its receptor typesin mediating unique cortical responses is unclear. NMDA receptorsare commonly thought to play a role in the development of corticalcircuitry, primarily as mediators of activity-dependent plasticity(Kirkwood and Bear, 1994; Katz and Shatz, 1996). AMPA receptorsare commonly thought to play a role in normal, ongoing transmissionbetween neurons. Yet, NMDA receptors in several regions of theadult brain, including the visual pathway, are known to be involvedin the transmission of sensory information (Fox et al., 1989;Miller et al., 1989; Sillito et al., 1990; Kwon et al., 1991).Because the two receptor types have different characteristics[importantly, NMDA receptors are sensitive to the membrane potential(for review, see Dingledine, 1999) and to GABAergic inhibition(Artola and Singer, 1987; Shirokawa et al., 1989; Schroeder etal., 1997)], they may have different functional roles in corticalintegration. A previous study (Fox et al., 1990) that examinedthe effect of NMDA receptor blockade in cat area 17 as a functionof stimulus contrast found a proportionate reduction of responsesat all contrasts. Conversely, application of NMDA caused a proportionalincrease in the response; application of quisqualate (a non-NMDAreceptor agonist) increased responses by a constant amount independentofcontrast.

We reasoned that selective blockade of AMPA or NMDA receptors while measuring responses would allow us to study the contributionof the other receptor to cortical cell properties. We have thuscombined extracellular recording with iontophoresis of receptorantagonists in layer 2/3 of cat area 17 to examine the role ofNMDA and AMPA receptors in creating emergent responses that areparticularly characteristic of these layers, namely, directionselectivity and complex cell responses (Hubel and Wiesel, 1962).Our data show that blocking NMDA receptors decreases the firingrate of cells but leaves direction selectivity and complex cellresponses unaltered. Thus, AMPA receptors are sufficient for generatingthese responses. Blocking AMPA receptors in layer 2/3 also decreasesthe firing rate but increases the direction selectivity of cellsand the spatial phase selectivity of complex cells, making complexcell responses similar to those of simple cells. Thus, NMDA receptorsare responsible for highly direction-selective responses. AMPAreceptors decrease spatial phase-selective simple cell responsesand are important for phase-invariant complex cellresponses.

Parts of these data have been published previously in abstract form (Rivadulla et al., 1999).

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

General preparation. All experiments were performed under protocols approved by Institutional Animal Care and Use Committeeof the Massachusetts Institute of Technology and were in accordwith National Institutes of Health guidelines. Adult female catsweighing between 1.5 and 2.5 kg were used. Animals were initiallyanesthetized with ketamine (15 mg/kg) and xylazine (1.5 mg/kg).Atropine (0.04 mg/kg) was applied to reduce tracheal secretions.A tracheotomy was performed. During the experiment, the animalwas anesthetized with isofluorane (typically 1%) in nitrous oxide(60%) and oxygen (40%). The level of anesthesia was titrated carefullyon the basis of the physiological state of the animal. The heartrate was continuously monitored and maintained at ~180 beats/min.Expired CO₂ was maintained at 4% by adjusting the respiratoryrate and the inspired volume. Body temperature was automaticallymaintained at 37.5° C with a heating blanket and a rectal probe.A craniotomy and durotomy were performed at Horsley-Clark coordinatesAP0 to 7 mm posterior and from the midline to 4 mm lateral. Astainless steel chamber was cemented to the skull with dentalacrylic. Warm 1% agar was applied to the cortical surface. Muscularparalysis was induced with Norcuron (Organon; 0.1 mg/kg), andthe animal was artificially ventilated. Paralysis was maintainedduring the experiment with a continuous infusion of Norcuron (0.2mg·kg¹·hr¹, i.v.). A mixture of 5% dextrose and lactated Ringer's solutionwas continuously infused (4 ml/hr, i.v.) to maintain bodyfluids.

Pupils were dilated with atropine, and nictitating membranes were retracted with phenylephrine HCl. The eyes were protectedwith contact lenses and focused at a distance of 57 cm. The opticdisks and retinal blood vessels were projected on a screen situatedat the same distance to determine the position of the area centralis.Receptive fields were first hand-plotted using flashing and movingbars and classified as simple or complex (Hubel and Wiesel, 1962).Computer-controlled visual stimuli consisted of drifting square-wavegratings that were presented on a monitor with a mean luminanceof 24 cd/m² at a contrast of 0.8. The grating spatial and temporal frequencywas set near-optimally for each cell. The typical spatial frequencywas 0.5 cycle/degree, corresponding to at least one (and usuallymore) grating cycle within the receptive field. The typical temporalfrequency was 1 Hz. Stimuli were presented at eight orientationseach at two opposite directions of motion (for a total of 16 directions).Each stimulus was presented for 2.5 sec; after it was flashedon, it remained stationary for the first 0.5 sec and was thendrifted for the next 2 sec. Stimuli were presented in random orderand included two blank presentations to obtain spontaneous activity.Responses were collected for the entire duration of the stimulusand were averaged from seven presentations of each stimulus. Responsesused for analysis were based on the total number of spikes obtainedduring stimulus motion (2 sec). Spontaneous activity was subtractedfrom the total before calculation of the directionindex.

Extracellular recording and iontophoresis. Multibarreled pipettes (three to five barrels) were used for extracellular recordingand iontophoretic ejection of drugs. The barrels were filled withNaCl (3 M) for recording, D-2-amino-5-phosphonovaleric acid (APV;50 mM), pH 8, 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX; 1 mM),pH 8, bicuculline methiodide (20 mM), pH 4, and fast green tomark the recording site. We used methods similar to those mentionedin the literature (Fox et al., 1990; Sillito et al., 1990) andused by us previously (Kwon et al., 1991) in analogous experimentalconditions to establish a specific effect of CNQX on AMPA receptorsand of APV on NMDA receptors at the applied doses. Briefly, ejectioncurrents were in the range of 10-40 nA. After control data werecollected, a drug was ejected until the visual response of thecell was diminished with respect to the control condition andreached a stable level of response. This usually happened after2-3 min of continuous ejection of CNQX or APV. Stability was ascertainedby comparing responses collected during the first and the lastset of trials and establishing that there were not significantdifferences in the responses. Effective doses of CNQX to antagonizeAMPA and not NMDA receptors were established by (1) ejecting apulse of AMPA without, and then with, concurrent ejection of CNQXto demonstrate that CNQX antagonized the AMPA response and (2)ejecting a pulse of NMDA without and with concurrent ejectionof CNQX to demonstrate that CNQX had no effect on the NMDA response.Similar trials were run to establish effective doses of APV, usingNMDA and AMPA as agonists. In specific cells, we tested the doseof CNQX and APV by applying them together; the visual responsewas abolished in each instance. The dose of bicuculline was establishedby observing the effect on visual responses alone. Typical ejectioncurrents were in the range of 15-25 nA. With these currents, aftera few seconds we achieved an increase in the visual and spontaneousactivity of cells that could be maintained for the duration ofthe visual stimulus without inducing burst discharges. When drugswere not ejected, a holding current of appropriate polarity wasapplied continuously. One of the barrels was filled with salineand used as a balance barrel. The pipette was moved with a mechanicalmicrodrive, and its tip was placed at a depth between 300 and800 µm from the cortical surface. When a cell was isolated, wemeasured its response to the gratings and repeated the same protocolduring ejection of APV, CNQX, or bicuculline and once more aftera period of recovery. Only cells that showed recovery of responsesto within 75% of control values were included in this study. Aftereach penetration, we made a deposit of fast green that allowedus to confirm the recordingsite.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The results described here were obtained from 42 cells recorded in the supragranular layers of area 17 in adultcats.

Effect of AMPA and NMDA receptors on visual responses

Figure 1 illustrates the effects on visual responses of area 17 neurons when AMPA and NMDA receptors were blocked separately.We analyzed the effect of primarily NMDA-mediated responses (whenAMPA receptors were blocked by iontophoresis of CNQX) and of primarilyAMPA-mediated responses (when NMDA receptors were blocked withAPV) by measuring proportional reductions in responses in thepreferred and nonpreferred directions. Figure 1A shows a cellin which AMPA receptor blockade by iontophoresis of CNQX reducedresponses in the preferred direction by 59% (39 spikes/sec) andresponses in the nonpreferred direction by close to 100% (42 spikes/sec).In 94% (30/32) of the studied cells, AMPA receptor blockade produceda decrease in the firing rate. In 87% (26/30) of cells, the decreasewas proportionally greater in the nonpreferred direction thanin the preferred direction; in three cells, the decrease was similar(80%) in both directions, whereas in one cell, all responses wereabolished by CNQX.

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Figure 1. CNQX and APV have different effects on direction-selective visual responses of layer 2/3 cells. A, Direction-tuning curves of a complex cell in the control condition, during CNQX iontophoresis, and after recovery. B, Direction-tuning curves from another complex cell in the control condition, during APV iontophoresis, and after recovery. C, Scatter plot for all of the cells in our study showing the effect of CNQX (n = 30) and APV (n = 27) in terms of proportion to the peak response of cells. Recov, Recovery.

Blockade of NMDA receptors also reduced the firing rate in 77% (27/35) of area 17 cells, affecting both preferred and nonpreferredresponses. For example, in the cell shown in Figure 1B, iontophoresisof APV reduced the preferred response by 46% (30 spikes/sec) andthe nonpreferred response by 51% (12 spikes/sec). The percentagereduction obtained with APV was comparable in the nonpreferredand preferred directions, indicating that AMPA receptors contributeto responses in bothdirections.

Figure 1C shows a scatter plot of the effects of CNQX and APV on preferred and nonpreferred responses in each of the cellsin our sample, expressed as a percentage reduction of the peakresponse. CNQX and APV had similar effects on preferred responses,but the reduction in nonpreferred responses was significantlygreater under CNQX than under APV (p < 0.01, t test). APV hadequivalent effects on the two components in proportional terms(Fig. 1C) (p > 0.05), whereas CNQX reduced nonpreferred responsessignificantly more than preferred responses (Fig. 1C) (p < 0.01).Thus CNQX and APV affected preferred and nonpreferred responsecomponentsdifferently.

Effects on direction selectivity

Blockade of AMPA receptors had dramatic effects on the direction selectivity of area 17 cells. Because of the drastic reductionin nonpreferred responses, responses that remained in the presenceof CNQX were primarily in the preferred direction. The directionindex [DI = (maximum response $-$ opposite response)/maximum response]under CNQX for our cell population (n = 29 cells) was significantlygreater than that in the control condition (Fig. 2A) (p < 0.01,Kolmogorov-Smirnov test). Indeed, nearly half the cells had anindex >0.9, indicating preferred responses that were >10 timeslarger than nonpreferred responses. In contrast, the DI underAPV for our population was not different from that of control(Fig. 2B) (p > 0.05, Kolmogorov-Smirnov test), consistent withthe data of Figure 1, in which APV caused a proportional reductionin preferred and nonpreferred responses. These results demonstratethat responses that remain after AMPA receptor blockade are highlyskewed toward the preferred direction whereas responses that continueafter NMDA receptor blockade are proportional to control responsesin both preferred and nonpreferred directions.

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Figure 2. Effect of CNQX and APV on the direction index of layer 2/3 cells. A, Cumulative histogram showing the effect of CNQX (n = 30). B, Cumulative histogram showing the effect of APV (n = 27). C, Histogram showing the effect of APV and CNQX on the variability of the DI. The x-axis represents the SD of the DI calculated trial by trial, which we used as a measure of the variability. The y-axis represents the number of cells in each bin.

Blockade of AMPA receptors not only leads to an increase in the DI but also to a decrease in the variability of the index.The SD of the DI was calculated as a measure of the variabilitybetween trials. Figure 2C shows the SD of the population in thecontrol condition and during CNQX and APV ejection. The valueswere significantly lower under CNQX than during control conditions(p < 0.01, t test). APV did not produce any change when comparedwith the control values (p > 0.05). Thus, direction-selectiveresponses mediated by NMDA receptors alone are much more reliablethan are responses mediated by AMPA receptors alone or controlresponses mediated by a combination of NMDA and AMPAreceptors.

Blocking inhibition increases preferred and nonpreferred responses, allowing a direct examination of whether inhibition interactswith glutamate receptors to affect specific response components.Thus, we examined the effect of blocking inhibition concurrentwith blockade of AMPA responses (Fig. 3) or NMDA responses (Fig.4) in preferred and nonpreferred directions. Figure 3A shows direction-tuningcurves from a cell under different conditions. In the controlcondition, this cell preferred a direction of 225 degrees andhad a DI = 0.67. During iontophoresis of CNQX, the preferred responsewas reduced substantially (by 22 spikes/sec or 60%), whereas thenonpreferred response was reduced to zero (by 10 spikes/sec),causing a DI = 1.0. Bicuculline made the orientation tuning broader;the firing rate of the cell increased by 76% in the preferreddirection and by 235% in the nonpreferred direction, decreasingthe DI to 0.36. Simultaneous ejection of CNQX now reduced preferredand nonpreferred responses approximately proportionately (correspondingto reductions of 34 and 25 spikes/sec, respectively) with respectto the bicuculline condition and led to a DI = 0.5. Thus, thereis a substantial non-AMPA (i.e., NMDA)-mediated component presentin the nonpreferred direction during bicuculline ejection, whichpersists during application of CNQX plus bicuculline and reducesthe DI relative to CNQX alone.

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Figure 3. Interactions between AMPA and GABA receptors during direction-selective responses. A, Direction-tuning curves of a complex cell in the control condition and during ejection of CNQX, bicuculline, and both simultaneously. B, Peristimulus time histograms of responses from another complex cell showing the control response and the effect of the drugs on the preferred (shown in black) and nonpreferred (gray) directions. Each histogram is the average response to seven stimulus presentations and shows the entire 2.5 sec of stimulus duration; the grating was stationary for the first 500 msec and drifted for the next 2 sec. C, Bar histogram showing the mean value (± SD) of the direction index for the population of cells in the different conditions (n = 4).

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Figure 4. Modulation of NMDA activity by GABA during generation of direction-selective responses. A, Direction-tuning curves from the same cell shown in Figure 3A in the control condition and during ejection of APV, bicuculline, and both simultaneously. B, Peristimulus time histogram of nonpreferred responses of two simple cells showing the effect of bicuculline and APV plus bicuculline. See the legend to Figure 3 for details. Blockade of inhibition by bicuculline preferentially increases the nonpreferred response, because of primarily an NMDA-mediated component; simultaneous application of APV reduces the response to the control level. Thus, GABAergic inhibition preferentially affects the NMDA response component in the nonpreferred direction. C, Bar histogram showing the mean (± SD) of the direction index for the population of cells in the different conditions (n = 4).

Figure 3B shows in more detail the effect of combining bicuculline with CNQX, in a different cell. The black line representsthe peristimulus time histogram (PSTH) in the preferred direction,and the gray line represents the PSTH in the nonpreferred direction.Bicuculline increased both preferred and nonpreferred responses(see Fig. 3B, right, the compressed scale on the y-axes). DuringCNQX ejection the cell became highly directional because of anear-complete reduction of nonpreferred responses. However, withCNQX and bicuculline applied concurrently, there was a proportionatelysimilar decrease in preferred responses (peak reduction, 37 spikes/sec)and nonpreferred responses (41 spikes/sec) compared with the bicucullinecondition. The effect of concurrent application of CNQX and bicucullineon preferred and nonpreferred responses was spread throughoutthe stimulus time period. These results were similar in all testedcells.

The average DI in the different conditions involving blockade of inhibition and AMPA receptors in all of the cells studied(n = 4) is shown in Figure 3C. Application of CNQX alone increasedthe DI of cells relative to that of control (p < 0.05, t test).Bicuculline alone decreased the DI relative to that of control(p < 0.05), principally by a disproportionate increase in nonpreferredresponses (Fig. 3A). Concurrent application of CNQX and bicucullineremoved proportional response components from preferred and nonpreferreddirections, leaving the DI unchanged (p > 0.05). This is in contrastto CNQX application with inhibition intact, which causes a disproportionatereduction in nonpreferred responses and an increase in the DI(compare Figs. 1C, 2A).

The nonpreferred response that remains after concurrent ejection of CNQX and bicuculline is mediated by NMDA receptors, indicatingthat GABAergic inhibition significantly regulates the NMDA responsecomponent in the nonpreferred direction. To test this hypothesis,we compared the response under bicuculline at the same time thatwe blocked the NMDA response. Figure 4A shows direction-tuningcurves from the same cell shown in Figure 3A. During APV iontophoresis,the nonpreferred response of the cell was reduced by 50% (from10 to 5 spikes/sec), and the preferred response was reduced by58% (from 31 to 13 spikes/sec). Bicuculline increased the nonpreferredresponse proportionately more than the preferred, but the effectof bicuculline was countered rather precisely by concurrent ejectionof APV; i.e., APV now reduced nonpreferred responses to a disproportionatelygreater extent. This effect of APV, in the presence of bicuculline,on nonpreferred responses was observed in all cells tested (n= 4). Figure 4B shows PSTHs from two different cells respondingin the nonpreferred direction, each in the control condition,during bicuculline ejection and during simultaneous ejection ofbicuculline and APV. Bicuculline clearly increased the firingrate of each cell, and the effect was reversed by APV throughoutthe stimulus duration. Figure 4C shows the DI in the differentconditions averaged for the four cells. Importantly, bicucullinereduced the DI compared with the control or APV condition (p <0.05, t test), but the DI was almost completely restored by theconcurrent application of APV (p < 0.05). The percentage reductionin responses obtained during application of APV plus bicuculline,compared with bicuculline alone, was greater in the nonpreferredthan the preferred direction (p = 0.05). This contrasts with theeffect of APV with intact inhibition (Fig. 1C), which causes proportionatelythe same reduction in nonpreferred and preferred responses. Thus,GABAergic inhibition acts to reduce NMDA-mediated responses preferentiallyin the nonpreferreddirection.

Effects on phase selectivity of simple and complex cells

If AMPA receptors contribute to both preferred and nonpreferred responses whereas NMDA receptors contribute disproportionatelyto preferred responses, the two receptors may have specific rolesin other kinds of integration that occur in the superficial layersof area 17. Thus, we examined the time course and relative phaseof responses in simple and complex cells during blockade of AMPAand NMDA receptors. We classified cells as simple or complex onthe basis of the structure of the receptive field (Hubel and Wiesel,1962). CNQX and APV affected the DI of simple cells (n = 13) andcomplex cells (n = 17) to a similar extent (p > 0.05, t test).However, AMPA receptor blockade changed the response phase andmodulation of complex cells. Figure 5A, left, shows PSTHs of acomplex cell responding in the preferred stimulus direction inthe control condition, during CNQX ejection, and after recovery.The control PSTH shows the typical absence of clear modulationin a complex cell response when stimulated with a drifting grating.CNQX reduced the firing rate but also changed the temporal patternof response. There was now a clear modulation of the response,similar to that expected from a simple cell rather than a complexcell. Iontophoresis of APV also reduced responses in the preferreddirection but did not change the temporal pattern of response(Fig. 5A, right). In simple cells, neither CNQX nor APV causeda substantial change in the temporal response pattern (Fig. 5B).

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Figure 5. AMPA receptors underlie the spatial phase-insensitive responses of complex cells. A, Peristimulus time histograms showing the response of two complex cells to a drifting grating moving in the preferred direction during the control condition and ejection of CNQX (left) and APV (right) and after recovery. See the legend to Figure 3 for details. During CNQX ejection, the response of the cell is modulated substantially by the grating; arrowheads show the response of the cell at the grating temporal frequency (1 Hz). During APV ejection, there is a reduction in the response but no pronounced phase-selective modulation. B, The effect of CNQX (left) and APV (right) on the response of a simple cell, showing little change in the temporal modulation of the response.

We calculated the mean (F0) and first (F1) Fourier components of response to drifting gratings from the PSTHs in the controlcondition and during ejection of CNQX or APV. The F1/F0 ratioprovides a measure of the modulation of response in a cell; ahigh ratio (>1) characterizes simple cells, whereas a low ratio(<1) is characteristic of complex cells (Movshon et al., 1978a,b;Skottun et al., 1991). The histogram in Figure 6A shows the F1/F0values obtained for our population in control conditions. Thehistogram clearly shows a bimodal distribution of cells indicativeof the existence of two subpopulations, with complex cells atratios <1 and simple cells at ratios >1.

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Figure 6. Effect of CNQX and APV on responses of simple and complex cells. A, Histogram of F1/F0 values of simple and complex cells in the control condition. F1 is the amplitude of the first Fourier component of response, showing modulation at the grating temporal frequency. F0 is the DC or mean response level. B, Scatter plot showing the change in F1/F0 for each complex cell (top; n = 16) and simple cell (bottom; n = 13) during CNQX and APV ejection. C, Histogram showing the variation in the F1/F0 ratio under CNQX and APV for simple and complex cells. The F1/F0 ratio increases significantly for complex cells under CNQX, denoting an increase in the temporal modulation of responses by the grating.

The scatter plots in Figure 6B show the effect of CNQX and APV on the F1/F0 ratio for each cell in our population. CNQX causeda significant increase in the F1/F0 ratio in complex cells comparedwith control (n = 16) but had little effect on simple cells (n= 13). APV had little effect on the F1/F0 ratio in either complexor simple cells relative to control (n = 16 complex cells, 13simple cells). The average change in F1/F0 for the different conditionsis shown in Figure 6C. Only CNQX application to complex cellssignificantly changes the F1/F0 ratio (p < 0.01, Kolmogorov-Smirnovtest). Thus, AMPA receptors appear to mediate the spatial phaseindependence of complex cell responses in the superficial layersof area 17 by nonspecifically decreasing phase-selectivemodulation.

Inhibition has been proposed to contribute to the generation of simple and complex cell properties; specifically, blockadeof inhibition widens On and Off subfields of simple cells, andthe increased overlap between subfields might make their responsessimilar to those of complex cells (Sillito, 1975; Pernberg etal., 1998) (see also Discussion). We therefore blocked inhibitionwith bicuculline to examine whether the F1/F0 ratio was reduced,particularly in simple cells to make responses more complex-like,and combined it with the ejection of CNQX to examine whether theratio was subsequently increased, reverting responses to thoseresembling simple cells. Figure 7A shows PSTHs from a simple cellresponding to a drifting grating moving in the preferred direction,in the control condition and during bicuculline application. Bicucullineincreased the firing rate but did not substantially modify themodulation of the response (F1/F0 = 1.59 in the control conditionand 1.34 during bicuculline application). Figure 7B shows thatthere was no effect on the F1/F0 ratio of bicuculline applicationor of CNQX applied separately or together with bicuculline onsimple cells (p > 0.05, t test, for all comparisons; n = 3). Incomplex cells, there was a possible decrease in the F1/F0 ratioduring bicuculline application (p = 0.2). However, in agreementwith data shown previously (Figs. 5, 6), application of CNQX causedan increase in the ratio when applied alone or together with bicuculline(p = 0.05 for each comparison; n = 3). APV had no effect on theF1/F0 ratio of either simple cells or complex cells when appliedalone or together with bicuculline (p > 0.05; n = 3). Thus, blockadeof inhibition does not affect temporal response modulation insimple or complex cells, and the effect of blocking AMPA receptorsis to increase phase-selective modulation even when inhibitionis removed.

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Figure 7. Blockade of inhibition does not affect the temporal modulation of simple or complex cell responses. A, Peristimulus histogram of the response of a simple cell to a grating drifting in the preferred direction, in the control condition and during bicuculline application. See the legend to Figure 3 for details. B, The effect of bicuculline, CNQX, and bicuculline plus CNQX on F1/F0 values of simple cells (left; n = 3) and complex cells (right; n = 3). Vertical bars show the mean (± SD).

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We have used direction selectivity and modulation of phase selectivity in simple and complex cell responses as probes forthe function of AMPA and NMDA receptors in the supragranular layersof area 17. By combining extracellular recording and iontophoresisof receptor blockers, we demonstrate the following results: (1)Blocking AMPA receptors removes a proportionately larger componentfrom nonpreferred compared with preferred responses and increasesdirection selectivity. The remaining responses are mediated byNMDA receptors and are overwhelmingly in the preferred direction.(2) Blocking NMDA receptors removes proportional components frompreferred and nonpreferred responses and preserves directionalselectivity. Because the remaining responses are mediated by AMPAreceptors, these receptors are sufficient for direction selectivity.(3) Blocking inhibition preferentially enhances the contributionof NMDA receptors to nonpreferred responses and reduces directionselectivity. Thus, inhibition contributes to direction selectivityby reducing NMDA responses in the nonpreferred direction. (4)Blocking AMPA receptors increases the modulation of complex cellresponses by a drifting grating stimulus. Thus, AMPA receptorsdecrease the selectivity of complex cells for spatial phase orthe spatial location of visual stimuli. (5) Blocking NMDA receptorsor inhibition has little effect on the temporal modulation ofsimple or complex cell responses. Together, these results allowus to propose specific roles for NMDA and AMPA receptors in directionselectivity in the superficial layers of area 17 and in the generationof phase selectivity by simple and complex cells in theselayers.

Direction selectivity in supragranular layers of cortex

Direction selectivity first appears in simple cells of layer 4 in area 17 (Hubel and Wiesel, 1962), where NMDA receptors arenot present in significant proportions (Rosier et al., 1993; Gordonet al., 1995; Gutierrez-Igarza et al., 1996) and contribute littleto visual responses (Fox et al., 1989, 1990; but see Miller etal., 1989). The mechanism(s) by which direction selectivity isgenerated and whether the mechanism is similar in various corticallayers remain unresolved. One hypothesis is that inhibition reducesthe response in the nonpreferred direction (Barlow and Levick,1965; Goodwin and Henry, 1975; Bishop et al., 1980; Ganz and Felder,1984). The hypothesis is supported by pharmacological studiesin cat (Sillito, 1975, 1977; Tsumoto et al., 1979; Nelson et al.,1994; Crook et al., 1997, 1998) and monkey (Sato et al., 1995),demonstrating that blockade of inhibition in cortical cells inducesa loss of selectivity to the direction of stimulus motion. Analternative hypothesis is that there is enhancement of excitationin the preferred direction. It has been shown (Reid et al., 1987,1991; McLean and Palmer, 1989; Jagadeesh et al., 1993, 1997; Livingstone,1998; Murthy et al., 1998) that simple cells in area 17 have asymmetriesin the time course of the response evoked from different positionsof the receptive field. Linear summation of these asymmetriesallows one to predict the direction preference of the cell butalso leads to an overestimation of the response in the nonpreferreddirection. Recurrent excitation has been proposed as a nonlinearmechanism by which responses can be increased in the preferreddirection (Douglas et al., 1995; Suarez et al., 1995). Recently,it has been postulated (Livingstone, 1998) that inhibition cansculpt the spatiotemporal profile of the receptive field, accentuatingspatiotemporal asymmetry and increasing direction selectivity,particularly in layer 4 (Murthy and Humphrey, 1999; see also Tayloret al., 2000).

A fundamental difference between layers 2/3 and 4 is the presence in supragranular layers of NMDA receptors, where they havebeen shown to participate in transmission in vivo (Fox et al.,1989, 1990) and in vitro (Shirokawa et al., 1989). Our data indicatethat AMPA and NMDA receptors both contribute to direction selectivityin supragranular layers (Fig. 8A). AMPA receptors are sufficientfor generating direction selectivity (Fig. 8C), either becauseinputs to the superficial layers conveyed by AMPA receptors arealready biased for direction or because feedforward and recurrentconnections mediated by AMPA receptors generate direction selectivitywithin these layers (Douglas et al., 1995). NMDA receptors bythemselves can generate highly direction-selective responses (Fig.8B), by summing and/or amplifying responses to the preferred stimuluswhile contributing less to nonpreferred responses because of closeGABAergic control. One possibility is that NMDA receptor activationis possible only with enough excitation in the preferred direction.However, a comparison of the nonpreferred and spontaneous responsesthat remain after CNQX application (spontaneous activity in ourpopulation of cells is reduced on average by only 28% under CNQX,whereas nonpreferred responses are reduced by 88%) suggests thatthe reduced contribution of NMDA receptors to nonpreferred responsesis likely mediated by active inhibition rather than simply beinga function of overall response magnitude: spontaneous activityoccurs under less inhibition than nonpreferred responses and remainssignificantly greater after AMPA receptor blockade.

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Figure 8. Schematic representation of the effect of NMDA and AMPA receptors on direction selectivity and their regulation by GABA. A, In control conditions, direction-selective cells in layer 2/3 have both AMPA and NMDA components that contribute to preferred and nonpreferred responses. Shown here is the hypothetical contribution of the two components to a cell with direction index = 0.6, which is approximately the 50th percentile of cells in our sample (Fig. 2A,B). Hypothetical responses are shown normalized to the peak response, and the response scale applies to B-E as well. B, CNQX ejection removes the AMPA component and leaves the NMDA component, which contributes prominently to responses in the preferred direction. NMDA-mediated responses in the nonpreferred direction are reduced disproportionately by GABAergic inhibition, leading to a high direction index. C, Ejection of APV leaves the AMPA component, which contributes similarly to both preferred and nonpreferred directions, causing no change in the direction index. D, The NMDA-mediated response, particularly that in the nonpreferred direction, is modulated importantly by GABAergic inhibition. Simultaneous application of CNQX and bicuculline leads to a disproportionate increase in the nonpreferred response and to a decrease in the direction index. E, The AMPA-mediated response is increased proportionately in both directions by removal of inhibition. Simultaneous ejection of bicuculline and APV increases both the preferred and nonpreferred response and causes no change in the direction index. F, GABAergic inhibition reduces both AMPA- and NMDA-mediated responses and particularly the NMDA responses in the nonpreferred direction. Bicuculline thus increase the nonpreferred response more than the preferred response, leading to a decrease in the direction index. The hypothetical responses in F are normalized differently from those in A-E.

Two lines of evidence indicate that GABAergic inhibition regulates the reduced contribution of NMDA receptors to nonpreferredresponses. First, blocking inhibition by application of bicucullinedecreases the direction selectivity of cells (Fig. 8F), but thiseffect is reversed by simultaneous application of APV (Fig. 8E),indicating that release of inhibition facilitates NMDA responsesin the nonpreferred direction. Second, blockade of inhibitionconcurrent with AMPA receptor blockade by CNQX reduces directionselectivity (Fig. 8D). Bicuculline preferentially increases nonpreferredresponses, leaving a higher contribution of NMDA responses inthe nonpreferreddirection.

These data confirm and extend the findings of Fox et al. (1990) that APV causes a proportional reduction in responses of area17 cells to optimally oriented moving bars as stimulus contrastis increased, whereas application of NMDA increases responsesby a proportional amount and quisqualate increases responses byan absolute amount at all contrasts. Importantly, we studied responsesin different directions (as also simple and complex cell responses)with APV and CNQX and the modulation of NMDA and AMPA responsesby inhibition. NMDA-mediated responses in the nonpreferred directionare reduced nonlinearly by inhibition. Furthermore, the contributionof AMPA receptors to complex cell responses is much more thanaddition of a constant response component; rather, there is anonlinear change in the temporal modulation of the response. Theseargue for specific circuits that engage inhibition for generatingdirection-selective responses and AMPA receptors for generatingcomplex cell responses (see below and Fig. 9).

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Figure 9. Schematic illustrating the proposed circuits and distribution of receptors at specific connections. A, Inputs from the lateral geniculate nucleus (LGN) to cells in layer 4 of V1 are mediated primarily by AMPA receptors (see text for review). These cells provide feedforward inputs to layer 2/3 cells; our data indicate that these connections are mediated by NMDA (N) and AMPA (A) receptors. Inputs from the C layers and the medial interlaminar nucleus of the LGN to layer 3 are shown as dashed lines and are regarded as feedforward connections. Short-range excitatory connections between layer 2/3 cells appear to be mediated primarily by AMPA receptors, with a possible minor contribution from NMDA receptors. B, NMDA and AMPA receptors together provide direction-selective feedforward input to layer 2/3 cells. NMDA receptors contribute prominently to responses in the preferred direction (left response histogram), whereas their contribution to responses in the nonpreferred direction (right response histogram) is reduced substantially by GABAergic inhibition (circles). Such inhibition may be greater in the nonpreferred direction. C, Simple cells in layer 4 provide feedforward input to cells in layer 2/3 via NMDA and AMPA receptors. Our data suggest that short-range recurrent excitatory connections in layer 2/3 via AMPA receptors are responsible for reducing the spatial phase selectivity of simple cells and creating phase-invariant complex cell responses.

The possibility that inhibition regulates NMDA-mediated activity is consistent with other lines of evidence in area 17 (Artolaand Singer, 1987; Shirokawa et al., 1989; Schroeder et al., 1997).The relationship between GABAergic inhibition and NMDA functionis probably related to the voltage dependence of NMDA receptors;the binding of extracellular Mg²⁺ to the channel pore is highly dependent on membrane potential,and changes in the latter could significantly modulate NMDA receptor-mediatedactivity (for review, see Dingledine, 1999). The likely sourceof inhibition is GABAergic interneurons located within layer 2/3itself (Crook et al., 1998).

One caveat is that the iontophoresis technique does not allow definitive conclusions about whether all receptors on a cellare affected or whether other cells (either excitatory or inhibitory)in the vicinity could be modifying the responses of the recordedcell. However, the temporal effects of drug application were studiedin the first and the second half of the iontophoresis period inseveral cells and found to be similar. Furthermore, the effectof iontophoresis did not change with ejection time, indicatingthat most of the affected receptors were in the volume coveredby the antagonist since the start of iontophoresis (cf. Hicks,1984; Hupe et al., 1999).

Phase selectivity of simple and complex cell responses

In addition to examining the role of AMPA and NMDA receptors in direction selectivity, we examined their role in generatingsimple and complex responses in the supragranular layers, by analyzingthe temporal pattern of response of cells when they were stimulatedwith drifting gratings (Movshon et al., 1978a,b; Skottun et al.,1991). CNQX caused a dramatic change in complex cell responses,causing them to increase their temporal modulation and respondin a manner similar to that of simple cells. APV did not affectthe response modulation of complex cells, and the modulation ofsimple cell responses was unaffected by CNQX orAPV.

Recently, it has been proposed that complex cell responses arise as a consequence of decreasing the phase selectivity of simplecell responses by recurrent intracortical connections (Chanceet al., 1999). The model predicts that a decrease in intracorticalexcitation should cause complex cells to respond like simple cells.If AMPA receptors primarily mediate short-range intracorticalexcitation (see below), our results agree strongly with this prediction,demonstrating that during blockade of AMPA receptors complex cellsbehave as simple cells when stimulated with driftinggratings.

Another possibility is that feedforward inputs combined with modulation of inhibition could generate simple and complex cellresponses; in the absence of GABAergic inhibition, the spatialsegregation of simple cells is lost, and On and Off subregionsshow greater overlap (Sillito, 1975; Pernberg et al., 1998). Inour hands, bicuculline ejection did not change the temporal modulationof simple (or complex) cell responses. However, some specificdifferences between our study and the previous studies shouldbe noted. For example, Pernberg et al. (1998) used the reversecorrelation method with flashed bar stimuli to study the spatialseparation of On and Off subfields of cells in area 18. We studiedchanges in the temporal modulation of responses in area 17 usingdrifting gratings. Although the spatial and temporal propertiesof area 17 cells are related, the subfield expansion during bicucullineiontophoresis may not relate in a simple way to the temporal structureof the grating response. Finally, Pernberg et al. (1998) foundthe subfield expansion in three of six simple cells, and the resultsof both Pernberg et al. and the present study derive from a smallsample.

We propose that AMPA and NMDA receptors in layer 2/3 have different spatial distributions on cells, with both present on thesame cell but in different proportions at different inputs (Fig.9A). Both receptors mediate feedforward connections, and theseafferents provide the necessary input for direction selectivityin layer 2/3 (Fig. 9B). Our data are consistent with spatiotemporalasymmetry and enhancement of excitation in feedforward pathwaysas crucial for direction selectivity in layer 2/3, with a prominentrole for NMDA receptors in generating the preferred response anda role for GABAergic inhibition in reducing the nonpreferred response.In contrast to feedforward connections, local recurrent connectionsare mainly mediated by AMPA receptors (with a possible small contributionfrom NMDA receptors), and they are responsible for smearing thephase selectivity of simple cells to create phase-invariant complexcell responses (Fig. 9C).

The suggestion that short-range excitation between cortical cells is mediated primarily by AMPA receptors is consistent withthe fact that fast EPSCs that are evoked in supragranular layercells in area 17 by adjacent intralaminar stimulation are notAPV sensitive (Hirsch and Gilbert, 1991). In somatosensory cortex,intracellular recording of unitary EPSCs in layer 4 and the supragranularcortex indicates that both thalamocortical and intracortical EPSCsare mediated by AMPA receptors and have similar characteristics(Gil et al., 1999). In slices of area 17, white matter stimulationevokes EPSPs in the supragranular layers that have NMDA- and AMPA-mediatedcomponents (Shirokawa et al., 1989). Short-latency responses becauseof feedforward and local recurrent connections are primarily AMPAmediated, whereas long-latency responses because of horizontalconnections have significant NMDA components (Langdon and Sur,1990, 1992). Furthermore, long-range horizontal inputs to layer2/3 cells in area 17 can sum nonlinearly with feedforward or short-rangeinputs, indicative of NMDA receptor involvement in the long-rangeconnections (Yoshimura et al., 2000). Thus, it is likely thatthere is even finer spatial segregation of glutamate receptorsassociated with specific inputs on layer 2/3 cells. Together withthe modulation of responses (particularly those mediated by NMDAreceptors) by inhibition, the specific relationship between receptortypes and anatomical connections provides a rich substrate fordynamic control of emergent responses in thecortex.

  FOOTNOTES

Received Sept. 15, 2000; revised Dec. 18, 2000; accepted Dec. 18, 2000.

This work was supported by National Institutes of Health Grants EY07023 and NS39022 to M.S. and by a Fulbright-MEC Fellowshipfrom Spain to C.R. We thank James Schummers for insightful discussionsof this manuscript, Nigel Daw for comments, and Christine Waitefor herhelp.
Correspondence should be addressed to Dr. Mriganka Sur, Department of Brain and Cognitive Sciences, Massachusetts Instituteof Technology, E25-235, 45 Carleton Street, Cambridge, MA 02139.E-mail: msur{at}ai.mit.edu.

Dr. Rivadulla's present address: Neuroscience and Motor Control Group (NEUROcom), E U Fisioterapia, Campus de Oza, 15006 ACoruña,Spain.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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