Excitatory and Inhibitory Circuitry in the Superficial Gray Layer of the Superior Colliculus

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The Journal of Neuroscience, October 15, 2001, 21(20):8145-8153

Excitatory and Inhibitory Circuitry in the Superficial Gray Layer of the Superior Colliculus
Psyche H. Lee¹, Matthias Schmidt¹^,², and William C. Hall¹
¹ Department of Neurobiology, Duke University Medical Center, Durham, North Carolina 27710, and ² Department of Zoology and Neurobiology, Ruhr-University, D-44780 Bochum, Germany

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Stratum griseum superficiale (SGS) of the superior colliculus receives a dense cholinergic input from the parabigeminal nucleus.In this study, we examined in vitro the modulatory influence ofacetylcholine (ACh) on the responses of SGS neurons that projectto the visual thalamus in the rat. We used whole-cell patch-clamprecording to measure the responses of these projection neuronsto electrical stimulation of their afferents in the stratum opticum(SO) before and during local pressure injections of ACh. Thesecolliculothalamic projection neurons (CTNs) were identified duringthe in vitro experiments by prelabeling them from the thalamuswith the retrograde axonal tracer wheat germ agglutinin-apo-HRP-gold.In a group of cells that included the prelabeled neurons, EPSCsevoked by SO stimulation were significantly reduced by the applicationof ACh, whereas IPSC amplitudes were significantly enhanced. Similareffects were observed when the nicotinic ACh receptor agonistlobeline was used. Application of the selective GABA_B receptorantagonist 3-[[(3,4-dichlorophenyl)-methyl]amino]propyl](diethoxymethyl)phosphinicacid blocked ACh-induced reduction in the evoked response. Incontrast, the ACh-induced reduction was insensitive to applicationof the GABA_A receptor antagonist bicuculline. The ACh-inducedreduction was also diminished by bath application of muscimolat the low concentrations that selectively activate GABA_C receptors.Because GABA_C receptors may be specifically expressed by GABAergicSGS interneurons (Schmidt et al., 2001), our results support thehypothesis that ACh reduces CTN activity by nicotinic receptor-mediatedexcitation of local GABAergic interneurons. These interneuronsin turn use GABA_B receptors to inhibit theCTNs.

Key words: acetylcholine; nicotinic ACh receptors; muscarinic ACh receptors; cholinergic circuits; interneurons; patch clamp; superior colliculus

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Projection neurons within the superficial gray layer, stratum griseum superficiale (SGS), of the superior colliculus relayvisual signals that arrive from the retina and cortex to diversestructures, including visuosensory regions of the thalamus, thedeeper, premotor layers of the superior colliculus, and the parabigeminalnucleus of the lateral midbrain tegmentum (Benevento and Fallon,1975; Robson and Hall, 1976; Harting, 1977; Harting et al., 1978;Sherk, 1979; Torrealba et al., 1981; Holstege and Collewijn, 1982;Reese, 1984; Taylor et al., 1986; Redgrave et al., 1987; Halland Lee, 1997; Künzle, 1997; Lee et al., 1997). Of the structuresthat receive projections from SGS, the parabigeminal nucleus (PBN)is of special interest because it also is the source of a densereciprocal projection of cholinergic axons that terminates withinSGS (Graybiel, 1978; Edwards et al., 1979; Watanabe and Kawana,1979; Roldan et al., 1983; Sefton and Martin, 1984; Taylor etal., 1986; Baizer et al., 1991; Jiang et al., 1996). The prominenceof this projection suggests that it plays an important role inthe modulation of the visual signals that are relayed by the SGSprojection neurons to other brainstructures.

Despite the prominence of this cholinergic pathway, few studies have addressed the question of its contributions to collicularfunction. One important exception is the recent in vivo demonstrationby Binns and Salt (2000) that iontophoretic application of theACh nicotinic receptor agonist lobeline reduces the amplitudeof visually evoked responses in the rat superficial gray layer.This reduction in the evoked response could be blocked by coapplicationof GABA_B, but not GABA_A, receptor antagonists. Binns and Salt(2000) proposed that ACh selectively excites a class of GABAergicinterneurons, which in turn reduce the responsiveness of the projectionneurons that transmit the visual signals from SGS to other brainstructures.

In the present study, we used in vitro whole-cell patch-clamp techniques to directly test their hypothesis at the cellularlevel. First, we measured the effects of ACh on the responsivenessof SGS neurons that were identified as projection neurons by prelabelingthem with thalamic injections of the retrogradely transportedmarker wheat germ agglutinin (WGA)-apo-HRP-gold (WAHG). Pharmacologicalexperiments then were used to identify the receptors responsiblefor the observed effects. Finally, the effects of ACh on projectionneurons were compared with its effects on a class of interneuronsthat were identified physiologically by their expression of GABA_Creceptors (Schmidt et al., 2001). Our results confirm the hypothesisthat ACh has a powerful inhibitory influence on the projectionneurons of the SGS. The results also support the hypothesis thatACh exerts this influence by exciting GABAergic interneurons,which in turn inhibit the projection neurons. The primary sourceof these cholinergic projections, the PBN, is retinotopicallyorganized and may serve to selectively filter the transmissionof signals from restricted regions of the visualfield.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Prelabeling. Because the effects of ACh within the SGS varied with cell type, the interpretation of our results depended onclassifying the recorded cells. To identify projection cells,colliculothalamic projection neurons (CTNs) in the SGS were retrogradelyprelabeled with WAHG (E-Y Laboratories, San Mateo, CA). The WAHGwas injected into the region of the dorsal lateral geniculate(dLGN) and lateral posterior thalamic (LP) nuclei several daysbefore the patch-clamp experiments. Both of these thalamic nucleiare known to receive projections from SGS (Reese, 1984; Tayloret al., 1986; Mooney et al., 1988; Hutsler and Chalupa, 1991).Putative interneurons were identified by their lack of retrogradelytransported WAHG, their morphology, and, for a particular classof interneurons, their expression of GABA_C receptors. The latterproperty was assessed by their responsiveness to low (0.5 mM)concentrations of muscimol (Schmidt et al., 2001).

All surgical procedures were approved by the Duke University Institutional Animal Care and Use Committee. Wistar rats weredeeply anesthetized with a mixture of ketamine (60 mg/kg) andxylazine (10 mg/kg). The cortex overlaying the posterior thalamuswas aspirated, and a modified Hamilton syringe tip filled withWAHG was visually guided into the caudal thalamus. Single or multipleinjections of 0.1-0.2 µl of WAHG were delivered into this regionto prelabel by retrograde axonal transport a population of theCTNs. Animals recovered from the surgery under intensive careand then were returned to their cages until they were used forthe slicerecordings.

Slice preparation. After a 3-10 d survival time, collicular slices were obtained from 23- to 35-d-old animals as describedpreviously (Lee and Hall, 1995). Briefly, the animals were deeplyanesthetized with an intraperitoneal injection of sodium pentobarbital(50 mg/kg) and perfused transcardially with ice-cold oxygenatedartificial CSF (ACSF) containing (in mM): 123 NaCl, 2.5 KCl, 1NaH₂PO₄, 1.3 MgSO₄, 26.2 NaHCO₃, 11 glucose, and 2.5 CaCl₂, towhich 2.0 kynurenic acid was added. Coronal slices (300 µm thick)were collected and stored in an interface chamber containing ACSFand kynurenic acid for 1 hr at 37°C and then at room temperatureuntilrecording.

Patch-clamp recordings. Whole-cell patch-clamp recordings were performed under visual guidance as described previously (Leeet al., 1997). Slices were transferred to a submersion-type recordingchamber and continuously superfused with oxygenated ACSF. In WAHG-injectedanimals, prelabeled cells were selected under visual control forrecording. Borosilicate micropipettes of 3-7 M $Omega$ impedance werefilled with internal solution containing 130 mM K-gluconate, 2mM Na-gluconate, 20 mM HEPES, 4 mM MgCl₂*6H₂O, 4 mM Na₂ATP*2.5H₂O,0.4 mM NaGTP, and 1 mM EGTA, to which 0.5% biocytin (MolecularProbes, Eugene, OR) was added. The measured membrane potentialswere corrected for the junction potential of $-$ 10mV.

Electrical stimulation was delivered to stratum opticum (SO) with an array of eight stainless steel wire electrodes (NB Labs,Denison, TX) spaced ~200 µm apart. Postsynaptic responses wereevoked with current pulses of 500 µsec duration and 3-100 µA inamplitude. These stimulus pulses were sufficient to evoke maximalsubthreshold responses. ACh (1 mM), 1 mM lobeline, or 4 mM methacholine(acetyl-B-methylcholine chloride; all from Sigma, St. Louis, MO)was injected through a micropipette of 1-5 M $Omega$ impedance by pressurepulses of 5-20 psi delivered by a pneumatic picopump (PV820; WorldPrecision Instruments, Sarasota, FL). The micropipette was locatedat distances ranging from 50 to 100 µm from the recorded cells.Single-cell responses were recorded before and for 20 sec afterthe onset of a continuous application of these agents. The significancesof ACh-induced effects were tested by one-wayANOVA.

All GABA receptor-related drugs were bath applied. Recordings were started 10 min after application. This time interval provedsufficient to achieve stable responses (Schmidt et al., 2001).The drugs applied were muscimol, bicuculline methiodide (Sigma),and 3-[[(3,4-dichlorophenyl)-methyl]amino]propyl](diethoxymethyl)phosphinicacid (CGP 52432) (Tocris Cookson, Ballwin,MO).

Postsynaptic responses were amplified by a standard patch-clamp amplifier (PC501A; Warner Instruments, Hamden, CT), digitizedat 20 kHz (Digidata 1200; Axon Instruments, Foster City, CA),and displayed, stored, and analyzed using pClamp6 software (AxonInstruments). After recording, slices were fixed in 4% phosphate-bufferedformaldehyde and were processed to visualize the recorded neuronsthat were labeled by diffusion into the cells of the biocytinin the internal solution (Hall and Lee, 1993; Lee and Hall, 1995).To reveal the biocytin, the sections were incubated in 10% methanoland 0.03% H₂O₂ in PBS, followed by 1% Triton X-100 in PBS, andthen they were freeze-thawed in 20% DMSO. Next, the sections wereincubated in avidin with 0.1% Triton X-100, followed by incubationin biotinylated HRP. Finally, the sections were incubated andthen reacted with 3,3-diaminobenzidine. Some sections were processedwithout intensification to allow simultaneous visualization ofboth biocytin and WAHG. Alternatively, the sections were reactedwith 3,3-diaminobenzidine intensified with cobalt and nickel toallow a detailed morphological characterization of thecells.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Identification of neurons

Whole-cell patch-clamp recordings were performed from a total of 56 neurons in SGS under voltage-clamp conditions. In 20 neurons,we could clearly visualize intracellular deposits of WAHG, whichwas used to retrogradely label CTNs from either the ipsilateraldLGN or LP nucleus. Whereas the WAGH allowed us to identify andselect for recording projection cells during the in vitro experiments,filling the cells with biocytin from the patch-clamp pipette allowedus to characterize the dendritic morphology of the recorded neuronsafter the experiments (Fig. 1). We fully recovered the dendriticmorphology of eight of the retrogradely labeled cells, and allof these were identified as narrow-field vertical cells (Fig.2A-D). We identified putative interneurons based on their dendriticmorphology, their lack of retrograde label, and their expressionof GABA_C receptors, as indicated by the reduction of EPSC amplitudesinduced by low concentrations of muscimol (Schmidt et al., 2001).

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Figure 1. Photomicrograph of a neuron showing dark WAHG spheres (arrows) that were retrogradely transported from injection sites in the thalamus together with the more evenly distributed biocytin, which diffused into the cell from the patch-clamp pipette. This photo was taken after 5 min of the DAB reaction without heavy metal intensification.

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Figure 2. Drawings of four retrogradely labeled colliculothalamic neurons that were filled with biocytin. The double-labeled cells can be identified as narrow-field vertical neurons that were located in upper SGS.

Influence of ACh on SGS neurons

Whereas electrical stimulation in SO may activate multiple inputs to the superficial layer with diverse effects, the integratedresponse typically evoked in CTNs at standard holding potential( $-$ 65 mV) is an EPSC. The EPSC was occasionally followed by a recognizableIPSC. However, because the EPSCs and IPSCs often overlapped intime, a distinctive IPSC was not alwaysvisible.

To study the influence of acetylcholine on evoked postsynaptic responses, we compared PSCs before and 20 sec after the onsetof the pressure injection of ACh close to the recorded neuron(Fig. 3). Application of ACh reduced EPSC amplitudes in 87% ofthe tested SGS neurons (33 of 38). In particular, all identifiedcolliculothalamic neurons showed significant decreases in EPSCamplitudes, which ranged from 11.2 to 79.1% (mean of 44.2 ± 23.2%;p < 0.01) of the control level.

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Figure 3. Drawing and recording of a CTN. A, The recorded CTN has the morphology of a narrow-field vertical cell. B, This record shows postsynaptic currents before (control) and at the end of a 20 sec application of ACh. The application of ACh reduced the amplitude of EPSCs evoked by stimulation of the optic layer (SO). The holding potential for this experiment was $-$ 65 mV. The arrow indicates the SO stimulus onset.

To characterize the ionic mechanism underlying the ACh-induced reductions in EPSC amplitude, we examined the effect of AChapplication on neurons clamped at different holding potentials.Figure 4 shows a representative example of such an experiment.At the standard holding potential of $-$ 65 mV, ACh application reducedthe EPSC amplitude of this cell by 27% (Fig. 4A). When the holdingpotential of the cell was lowered to $-$ 100 mV, which was belowthe reversal potential of Cl ( $-$ 71 mV) and close to the reversal potential for potassium ( $-$ 99mV) in our recording conditions, the evoked EPSC showed only asmall change after ACh application ( $-$ 7%) (Fig. 4B). However, whenthe cell was clamped at $-$ 110 mV, which was below the reversalpotential for potassium, the evoked EPSC after ACh applicationwas increased by 15% (Fig. 4C). This reversal of the ACh effectbelow the calculated reversal potential for potassium indicatedthat a potassium current might be responsible for the ACh-inducedreduction in EPSCs amplitude at the standard holding potential( $-$ 65 mV).

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Figure 4. Effect of the holding potential on ACh-induced PSC changes. Each set of traces shows PSCs before (control), at the end of a 20 sec application of ACh (ACh), and 2 min after ACh application (recovery). A, When the holding potential equaled $-$ 65 mV, ACh reduced evoked EPSC amplitude. B, At a holding potential of $-$ 100 mV, which was close to the reversal potential for potassium, ACh did not change EPSC amplitude. C, At 110 mV, which was below the reversal potential for potassium, the application of ACh increased EPSC amplitude. Arrows indicate SO stimulus onset.

Because this result implies an increased inhibitory input to CTNs during ACh application, we expected ACh-induced increasesof IPSC amplitudes when recording from CTNs clamped at more positiveholding potentials. A representative example is shown in Figure5. At normal holding potential ( $-$ 65 mV), ACh application induceda 20% reduction of the EPSC amplitude without a detectable effecton the IPSC amplitude (Fig. 5A). At a more positive holding potential( $-$ 40 mV), ACh application, in addition to reducing the EPSC amplitude( $-$ 49%), strongly increased the IPSC amplitude (+60%) (Fig. 5B).Similar IPSC amplitude increases (mean of 37.3 ± 21.5%; p < 0.01)induced by ACh application were observed in 80% (four of five)of cells tested.

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Figure 5. The inhibitory effect of ACh on IPSC amplitude. Each set of traces shows PSCs before (control), at the end of a 20 sec application of ACh (ACh), and 2 min after ACh application (recovery). A, At a holding potential of $-$ 65 mV, ACh reduced the EPSC amplitude. B, At a more positive holding potential of $-$ 40 mV, ACh application not only reduced the EPSC amplitude but also increased the IPSC amplitude. Arrows indicate SO stimulus onset.

Pharmacology of ACh effects

Visually evoked responses of SGS neurons recorded in vivo are dramatically reduced by iontophoretic application of nicotinicreceptor agonists but are only slightly reduced in the presenceof muscarinic ACh receptor agonists (Binns and Salt, 2000). Therefore,we tested whether our in vitro ACh-induced reductions could bemimicked by application of either the nicotinic ACh receptor agonistlobeline or the muscarinic ACh receptor agonistmethacholine.

The effect of the nicotinic receptor agonist lobeline on postsynaptic responses was tested in six SGS neurons (Fig. 6A). Inall cases, lobeline application resulted in a decrease of EPSCamplitudes similar to that observed after ACh applications (meanof 26%).

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Figure 6. The contributions of nicotinic and muscarinic receptors to the ACh-induced reductions in EPSC amplitude. Each set of traces shows PSCs before (control), at the end of a 20 sec application of ACh (ACh), and 2 min after ACh application (recovery). Applications of both the nicotinic ACh receptor agonist lobeline (A) and the muscarinic ACh receptor agonist methacholine (B) reduced the amplitude of the evoked EPSCs. Arrows indicate SO stimulus onset. AChR, ACh receptor.

The effect of the muscarinic receptor agonist methacholine on the EPSCs was tested in seven SGS neurons (Fig. 6B). Two narrow-fieldvertical cells, a horizontal cell, and an unidentified cell showedreduced EPSC amplitudes up to 31% (mean of 14%).

Influence of GABAergic inhibition

In vivo, the ACh-induced reductions of visual responses can be blocked by coapplication of antagonists to GABA_B receptorsbut not by coapplication of antagonists to GABA_A receptors (Binnsand Salt, 2000). We therefore examined ACh-induced effects duringpharmacological blockage of both GABA_A and GABA_Breceptors.

To study the consequence of blocking synaptic transmission through GABA_B receptors, we compared ACh-induced effects beforeand during bath application of the selective GABA_B receptor antagonistCGP 52432 (10 µM). A representative example of such an experimentis shown in Figure 7. In normal ACSF, when no CGP 52432 was present,ACh application reduced EPSC evoked in this cell by 32% (Fig.7A). In the presence of CGP 52432, the same ACh application didnot decrease the EPSC amplitude; instead a small increase (+4%)was observed (Fig. 7B). A comparable complete blockage of theACh-induced EPSC amplitude decreases was observed in 77% of thecells tested (10 of 13). In the remaining cells, ACh still inducedEPSC amplitude decreases during coapplication of CGP 52432, butthese decreases were significantly reduced compared with thosein normal ACSF.

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Figure 7. The contribution of GABA_B receptors to the ACh-induced reductions in EPSC amplitude. Each set of traces shows PSCs before (control), at the end of a 20 sec application of ACh (ACh), and 2 min after ACh application (recovery). A, In normal ACSF, ACh reduced the amplitude of the evoked EPSC in this WAHG-labeled narrow-field cell. B, In the presence of the GABA_B receptor antagonist CGP 52432, the ACh-induced reduction was blocked. Arrows indicate SO stimulus onset.

In another set of experiments, we tested whether a blockage of GABAergic transmission mediated by GABA_A receptors would alsoaffect ACh-induced EPSC amplitude reductions. In these experiments,we compared the ACh-induced effects before and during bath applicationof the GABA_A receptor antagonist bicuculline (20 µM). Figure 8illustrates the results from such an experiment. For this cell,ACh application reduced EPSC amplitude by 24% in the control situation,that is, when no bicuculline was present in the bath solution(Fig. 8A). In the presence of bicuculline (Fig. 8B), the EPSCduration in both ACh and control was strongly increased comparedwith the control situation. This indicates that a blockage ofGABA_A receptor-mediated synaptic transmission removed a significantinhibitory input to this neuron, which normally curtails the durationof evoked postsynaptic excitation. However, application of AChin the presence of bicuculline still reduced the EPSC amplitudeby 29%.

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Figure 8. The contribution of GABA_A receptors to the ACh-induced reductions in EPSC amplitude. Each set of traces shows PSCs before (control), at the end of a 20 sec application of ACh (ACh), and 2 min after ACh application (recovery). A, In normal ACSF (control), ACh reduced the evoked EPSC in this identified colliculothalamic projection neuron. B, This reduction was not blocked by the presence of the GABA_A receptor antagonist bicuculline, although bicuculline greatly prolonged the EPSCs, indicating that it blocked inhibitory inputs that curtail the evoked response of the cell. Arrows indicate SO stimulus onset.

The influence of bicuculline on ACh-induced effects was tested in nine SGS neurons in which ACh application alone significantlydecreased EPSC amplitudes. In 89% of these neurons (eight of nine),coapplication of bicuculline did not block or decrease the ACh-inducedreductions in the EPSC. When the effects of both CGP 52432 andbicuculline on the ACh-induced reduction of EPSC amplitude weretested in six neurons, in 83% (five of six), the ACh effects werecompletely blocked by CGP 52432 but remained unchanged in thepresence ofbicuculline.

In a final set of experiments, we tested whether a selective inactivation of GABAergic interneurons in SGS would diminishthe ACh-induced reductions of EPCS amplitudes. Because local GABAergicinterneurons, but not projection neurons, express GABA_C receptorsin SGS (Schmidt et al., 2001), GABA_C receptor activation can beused to selectively inactivate GABAergic interneurons. As hasbeen demonstrated in previous studies, bath application of muscimolat a low concentration in the range of 0.5 µM activates GABA_Creceptors without affecting GABA_A receptors (Schmidt et al., 2001).The effect of selectively inactivating interneurons using thismethod on the responses of a CTN neuron is shown in Figure 9.ACh application near this neuron, which exhibited the morphologyof a narrow-field vertical cell, reduced its EPSC amplitude by28% (Fig. 9A). In contrast, in the presence of 0.5 µM muscimol,which itself did not affect the EPSC amplitude, the reductionof the EPSC amplitude induced by ACh application was only 3% (Fig.9B). This suppression of the ACh-induced reduction in the EPSCmay be attributable to a selective inactivation of GABAergic interneuronspresynaptic to the recorded neuron. Overall, bath-applied muscimol,at a concentration of 0.5 µM, significantly reduced or completelyabolished ACh-induced EPSC amplitude decreases in 71% of the cellstested (10 of 14).

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Figure 9. The contribution of GABA_C receptors to the ACh-induced reductions in EPSC amplitude. Each set of traces shows PSCs before (control), at the end of a 20 sec application of ACh (ACh), and 2 min after ACh application (recovery). A, In normal ACSF, ACh reduced the amplitude of the evoked EPSC in this identified colliculothalamic narrow-field cell. B, In the presence of muscimol at a concentration of 0.5 µM (which selectively activates GABA_C receptors), the ACh-induced EPSC reduction was greatly diminished. Arrows indicate SO stimulus onset.

A summary of the results on CTNs is shown in Figure 10. ACh application reduced EPSC amplitudes by 39.3%, lobeline reducedthe amplitudes by 25.8%, and methacholine reduced them by 14.4%.Coapplication of CGP 52432 completely blocked the ACh-inducedeffects (mean EPSC amplitude reduction of 1.2%), and low concentrationsof muscimol strongly reduced ACh-induced the effects (10.4%).In contrast, coapplication of bicuculline did not change the ACh-inducedeffects (40.2%).

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Figure 10. The effect of ACh on CTNs. This chart shows the mean EPSC amplitude reductions (black horizontal bars), as well as the reductions for individual cells (filled circles) induced by application of ACh, lobeline, and methacholine. The effects on the ACh-induced reductions produced by the GABA_A receptor antagonist bicuculline, by the GABA_B receptor antagonist CGP 52432, and by muscimol at a concentration that selectively activates GABA_C receptors are also summarized.

Interneurons

Our classification of cells as putative GABAergic interneurons was based on their dendritic morphology, on the absence ofany retrograde label after the thalamic injections, and on thestrong inhibitory effect on their evoked responses observed inthe presence of 0.5 µM muscimol in the bath (Schmidt et al., 2001).Our sample of interneurons included one horizontal cell, fourpiriform cells, and four stellate cells. Whereas the horizontalcell and three of the piriform cells showed decreased EPSC amplitudesduring ACh application similar to those observed for projectioncells, ACh had the opposite effect on the remaining interneurons.Results from such a neuron are shown in Figure 11. In this cell,ACh increased the EPSC amplitude by 15% when the cell was clampedat the standard holding potential of $-$ 65 mV (Fig. 11A). Loweringthe holding potential to $-$ 100 mV, which was nearly at the reversalpotential for potassium, did not change the enhancing effect ofACh on the EPSC amplitude (Fig. 11B). These results were in clearcontrast to those obtained in all of the identified projectionneurons, in which ACh-induced reductions of the EPSC amplitudesdisappeared at this holding potential (Fig. 4).

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Figure 11. The effect of ACh on putative interneurons. Each pair of traces shows PSCs before (control) and at the end of a 20 sec application of ACh (ACh). A, In contrast to all recorded CTNs, the application of ACh enhanced the evoked EPSCs in this cell when the holding potential was $-$ 65 mV. B, ACh-induced EPSC amplitude increases remained relatively unaltered in this cell at a holding potential close to the potassium reversal potential ( $-$ 100 mV). Arrows indicate SO stimulus onset.

Three morphologically identified interneurons, one horizontal and two piriform-stellate cells, were tested for the effectof the muscarinic receptor agonist methacholine on EPSC amplitudes.Although EPSC amplitudes increased with methacholine applicationin both piriform-stellate cells, they remained relatively unchangedfor the horizontal cell (Fig. 12A). Similar to the results observedwith ACh, lowering the holding potential to $-$ 110 mV, which wasbelow the reversal potential for potassium, did not change theamplification effect of methacholine on the EPSCs generated bythe piriform-stellate cells (Fig. 12B,C).

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Figure 12. The contribution of muscarinic ACh receptors to the responses of putative interneurons. Each pair of traces shows PSCs before (control) and at the end of a 20 sec application of ACh (ACh). A, In contrast to its action on projection neurons, the muscarinic ACh receptor agonist methacholine did not change EPSC amplitude in an identified horizontal cell. B, In another putative interneuron, morphologically identified as a piriform cell, methacholine increased EPSC amplitude not only when the normal holding potential was $-$ 65 mV but also when the potential was clamped below the potassium reversal potential ( $-$ 110 mV) (C). Arrows indicate SO stimulus onset.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We investigated in vitro the influence of ACh on postsynaptic responses in rat SGS neurons. In colliculothalamic projectionneurons, local pressure injections of ACh, the nicotinic ACh receptoragonist lobeline, or the muscarinic ACh receptor agonist methacholinereduced the amplitudes of EPSCs that were evoked by electricalstimulation of the subjacent layer, SO. We propose that this ACh-inducedreduction is mediated through local GABAergic interneurons forthe following reasons. First, the ACh-induced EPSC decreases couldbe blocked by bath application of the GABA_B receptor antagonistCGP 52432. Second, bath application of muscimol at a low concentrationthat has been demonstrated to activate GABA_C, but not GABA_A, receptors(Schmidt et al., 2001) diminished the ACh-induced EPSC decreases.Because activation of GABA_C receptors is expected to selectivelyinactivate GABAergic interneurons in SGS (Schmidt et al., 2001),this result suggests that the ACh-induced reductions are mediatedby these interneurons. Third, at least a subpopulation of putativeGABAergic interneurons, as identified by both anatomical and physiologicalproperties, showed increased EPSC amplitudes in the presence ofACh. Together, these results support the hypothesis that ACh selectivelyexcites a population of GABAergic interneurons, which, in turn,exerts a GABA_B-mediated inhibitory influence on projection neuronsin SGS. The circuitry that we propose is responsible for theseeffects is diagramed in Figure 13.

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Figure 13. Circuit model to explain the observed effects of ACh on the colliculothalamic neurons in SGS. According to the model, ACh both presynaptically (nicotinic receptors) and postsynaptically (muscarinic receptor) excites a class of GABAergic interneurons. These interneurons, in turn, use GABA_B receptors to inhibit the CTNs. In the figure, the gold circles in the CTN soma represent WAHG that was retrogradely transported to the cell from an injection site in the thalamus. GABA_AR, GABA_A receptor; GABA_BR, GABA_B receptor; GABA_CR, GABA_C receptor; nAChR, nicotinic ACh receptor; mAChR, muscarinic ACh receptor; GluR, glutamate receptor.

Prelabeling with WGA-apo-HRP-gold

Fluorescent tracers have been used routinely to retrogradely label cells in living slices (Katz et al., 1984; Edwards et al.,1989). However, fluorescent tracers have disadvantages. First,epifluorescence illumination in the living slice may induce phototoxicityor free radical-induced membrane damage and thus increase thedifficulty of obtaining stable recordings (Mendez and Penner,1998). Although the phototoxic effects can be minimized by rapidlyswitching from fluorescence to bright-field optics, this procedureis cumbersome and time consuming. Second, fluorescence labelsoften bleach or fade, especially after histological processing.As an alternative to fluorescent tracers, we used WAHG as a retrogradetracer to prelabel the cells (Menetrey, 1985; Basbaum and Menetrey,1987; Winer et al., 1996). WAGH is visible in living slices andthus can be used to guide the recording pipette toward the labeledcells. WAGH also has the advantages that the gold label is easilyvisible under standard bright-field illumination, provides a permanentlabel that is still visible after the histological processingfor biocytin, and, most important, is inert and so causes no damageto the recorded cell. Finally, WAGH spreads only short distancesfrom the injection site and therefore can be precisely depositedin particular structures. For all of these reasons, we regardthis tracing method as a versatile tool for in vitro studies inwhich it is important to classify neurons by their efferentconnections.

Effects of ACh on evoked postsynaptic currents

The effects of ACh on EPSC amplitudes depended on cell type. That is, whereas ACh increased EPSC amplitudes in a populationof putative GABAergic interneurons, in all identified projectionneurons, it decreased EPSC amplitudes. Similar effects have beenreported recently in an in vivo study that examined the influenceof cholinergic transmission on visual responses of rat SGS neurons(Binns and Salt, 2000). In the in vivo experiments, iontophoreticalapplication of the nicotinic receptor agonist lobeline and themuscarinic agonist methacholine decreased visual responses. Becausethis reduction in visual responsiveness could be blocked by coapplicationof GABA_B, but not GABA_A, receptor antagonists, it was proposedthat ACh activates local GABAergic interneurons in SGS and thatthe increased activity of these GABAergic interneurons decreasesthe activity of SGS projection neurons (Binns and Salt, 2000).By prelabeling cells with WAHG that was conveyed by retrogradeaxonal transport from the thalamus, we were able to directly demonstratethat the application of ACh, or its agonists, reduces the responsivenessof colliculothalamic cells to input from the optic layer. Furthermore,our ability to block the ACh-induced reductions by either applicationof the GABA_B receptor antagonist CGP 52432 or selectively inhibitingGABAergic interneurons with low concentrations of muscimol confirmedthat the response reductions in the projection neurons are mediatedindirectly by GABAergic interneurons in SGS. Finally, by recordingfrom interneurons, we were able to confirm that, in contrast toall of the projection cells, a population of interneurons showsenhanced, rather than reduced, EPSCs in the presence ofACh.

Although the results support the hypothesis that the ACh-induced EPSC decreases observed in SGS projection neurons are mediatedby GABAergic interneurons, several observations indicate thatonly a subset of GABAergic SGS interneurons is involved. First,the strong disinhibitory influence of bicuculline indicates thata significant amount of the GABAergic inhibition on projectionneurons is mediated by GABA_A receptors (Fig. 8B). Second, evidencesuggests that inhibitory mechanisms mediated through GABA_A andGABA_B receptors have different functional roles, including surroundinhibition and response habituation, respectively (Binns and Salt,1997). Finally, in our sample of cells, a number of putative GABAergicinterneurons did not show EPSC increases when ACh or methacholinewas applied. In particular, the one morphologically identifiedhorizontal cell exhibited reduced rather than increased EPSCsin the presence of ACh. Whereas horizontal cells are thought tomediate their inhibitory influence on SGS projection neurons throughGABA_A receptors, the stellate and/or piriform cells may be presynapticto GABA_B receptors (Mize, 1992; Binns, 1999) and mediate the ACh-induceddecrease in the responsiveness of the SGS projectionneurons.

Nicotinic versus muscarinic ACh receptors

Both nicotinic and muscarinic ACh receptor agonists reduce visual activity of rat SGS neurons in vivo (Binns and Salt, 2000),and both receptor types are expressed at high levels in SGS (Clarkeet al., 1985; Zubieta and Frey, 1993; Perry and Kellar, 1995;Whiteaker et al., 2000). These results are consistent with ourobservation that both lobeline and methacholine can mimic ACh-inducedEPSC decreases in narrow-field vertical cells. The methacholine-inducedEPSC increases in the two tested piriform cells suggest that GABAergicinterneurons may be selectively excited through muscarinic AChreceptors. This activation would in turn decrease responses inprojection neurons that are postsynaptic to theseinterneurons.

Evidence suggests that the nicotinic ACh receptors are located presynaptically on retinal terminals (Prusky and Cynader, 1988).From our results, as well as from the results obtained in vivo(Binns and Salt, 2000), it seems reasonable to further proposethat nicotinic receptors are specifically expressed in retinalterminals that provide input to the GABAergic interneurons thatare connected to projection neurons through GABA_B receptors. Fromthe effects obtained with methacholine, it may be proposed thatinhibitory muscarinic ACh receptors are expressed by projectionneurons and GABAergic horizontal cells, whereas excitatory muscarinicACh receptors are specifically expressed by GABAergic interneuronswith piriform-stellate morphology. However, although both functionaltypes of muscarinic ACh receptors are present in SGS (Aubert etal., 1992; Zubieta et al., 1993; Levey et al., 1994), nothingdefinite is known about their cellularlocalization.

Functional role of the cholinergic input to SGS

Both in vivo (Binns and Salt, 2000) and in vitro (present study) experiments have demonstrated that ACh exerts a powerfulinfluence on the excitability of SGS neurons. These physiologicalresults are consistent with those from immunocytochemical studiesthat demonstrate a dense cholinergic neuropil in this layer (Hallet al., 1989; Henderson, 1989; Tan and Harvey, 1989; McHaffieet al., 1991; Jeon et al., 1993). Most of the axons that formthis neuropil arise from the parabigeminal nucleus in the lateralmidbrain tegmentum (Mufson et al., 1986; Hall et al., 1989; Tanand Harvey, 1989; McHaffie et al., 1991). This small, but denselypacked, group of cholinergic cells receives projections from theipsilateral SGS and in turn projects bilaterally to SGS in mammals(Edwards et al., 1979; Roldan et al., 1983; Mufson et al., 1986;Taylor et al., 1986; Hall et al., 1989; Baizer et al., 1991; Jianget al., 1996). Similar pathways are present in nonmammalian vertebratesranging from fish to birds, and, in the pigeon, excitation ofthe apparent parabigeminal nucleus homolog, nucleus isthmi parvocellularis,increases the inhibition of tectal cells (King and Schmidt, 1991a,b;Wang et al., 2000).

One clue to the function of this cholinergic pathway is the finding that the observed ACh-induced reductions in excitabilityof SGS projection cells are mediated by GABA_B receptors. Comparedwith GABA_A receptors, GABA_B receptors typically give rise to longer-lastingoutward currents that are slower to reach their peak and are accompaniedby small conductance changes (Bormann, 1988). These properties,together with the indirect route from SGS to the parabigeminalnucleus back to SGS, suggest that this cholinergic pathway doesnot contribute to the ongoing temporal and spatial modulationof visual inputs to SGS. One alternative is that the ACh-mediatedGABA_B currents deinactivate low-threshold channels by hyperpolarizingthe SGS projection cells (Crunelli and Leresche, 1991). Afterdepolarization by subsequent visual inputs to SGS, the projectioncells may generate Ca spikes with superimposed bursts of Na spikes(Scharfman et al., 1990). Such bursts have been observed in SGS(Lo and Mize, 2000) and may serve to amplify the responses ofSGS projection cells to salient stimuli that appear in the visualfield subsequent to an orienting movement. This amplified signalmay then be transmitted by the projection cells to other structures,including the visual cortex via the thalamus and the premotorcells of the deeper layers, which in turn may command a subsequentsaccade to a salient stimulus. A similar role for the bursts generatedby low-threshold Ca spikes has been proposed for sensory relaycells in the thalamus, and cholinergic pathways from the brainstemalso modulate this mechanism (McCormick and Pape, 1988; Guidoet al., 1995; Sherman, 1996; Reinagel et al., 1999). However,additional experiments will be necessary to establish that ananalogous mechanism functions in SGS to amplify novel visual signalsthat appear after a shift in the direction ofgaze.

  FOOTNOTES

Received May 21, 2001; revised July 2, 2001; accepted July 23, 2001.

This study was supported by National Institutes of Health Grant EY08233 and the Deutsche Forschungsgemeinschaft (a "Heisenberg"fellowship to M.S. and Sonderforschungsbereich 509 "Neurovision").We thank Dr. Michael Platt for his helpful comments on thismanuscript.
Correspondence should be addressed to Dr. Matthias Schmidt, Allgemeine Zoologie und Neurobiologie, Ruhr-Universität Bochum,ND 6/25, D-44780 Bochum, Germany. E-mail: mschmidt{at}neurobiologie.ruhr-uni-bochum.de.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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