Mechanisms Underlying Developmental Changes in the Firing Patterns of ON and OFF Retinal Ganglion Cells during Refinement of their Central Projections

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The Journal of Neuroscience, November 1, 2001, 21(21):8664-8671

Mechanisms Underlying Developmental Changes in the Firing Patterns of ON and OFF Retinal Ganglion Cells during Refinement of their Central Projections
Karen L. Myhr¹, Peter D. Lukasiewicz¹^,², and Rachel O. L. Wong¹
Departments of ¹ Anatomy and Neurobiology and ² Ophthalmology, Washington University School of Medicine, St. Louis, Missouri 63110

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Patterned neuronal activity is implicated in the refinement of connectivity during development. Calcium-imaging studies ofthe immature ferret visual system demonstrated previously thatfunctionally separate ON and OFF retinal ganglion cells (RGCs)develop distinct temporal patterns of spontaneous activity astheir axonal projections undergo refinement. OFF RGCs become spontaneouslymore active compared with ON cells, resulting in a decrease insynchronous activity between these cell types. This change inON and OFF activity patterns is suitable for driving the activity-dependentrefinement of their axonal projections. Here, we used whole-celland perforated-patch recording techniques to elucidate the mechanismsthat underlie the developmental alteration in the ON and OFF RGCactivity patterns. First, we show that before the refinement period,ON and OFF RGCs have similar spike patterns; however, during theperiod of segregation, OFF RGCs demonstrate significantly higherspike rates relative to ON cells. With increasing age, OFF cellsrequire less depolarization to reach their action potential thresholdand fire more spikes in response to current injection comparedwith ON cells. In addition, spontaneous postsynaptic currentsand potentials are greater in magnitude in OFF cells than ON cells.In contrast, before axonal refinement, there are no differencesin the intrinsic excitability or synaptic drive onto ON and OFFcells. Together, our results show that developmental changes inON and OFF RGC excitability and in the strength of their synapticdrives act together to reshape the spike patterns of these cellsin a manner appropriate for the refinement of theirconnectivity.

Key words: developing retina; activity-dependent segregation; ferret visual system; spike patterns; action potential threshold; spontaneous activity; ON-center ganglion cells; OFF-center ganglion cells

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In many parts of the developing CNS, the early patterns of connectivity are refined by processes that rely on action potentialactivity (Goodman and Shatz, 1993; Katz and Shatz, 1996). Temporalcues relayed by the activity patterns of presynaptic cells arethought to be key to the refinement process (for review, see Biand Poo, 2001; van Ooyen, 2001). In the ferret visual system,the axonal projections of functionally distinct ON-center andOFF-center retinal ganglion cells (RGCs) innervate distinct sublaminaswithin their central target, the dorsal lateral geniculate nucleus(dLGN) (Stryker and Zahs, 1983). ON and OFF sublamination occursbefore eye opening but requires neuronal activity (Hahm et al.,1991; Cramer and Sur, 1997) that is generated spontaneously bythe retina (Wong, 1999).

We observed previously that ON and OFF RGCs alter their activity patterns during development (Wong and Oakley, 1996). Beforethe period when ON and OFF retinal projections segregate, ON andOFF RGCs periodically undergo synaptically driven rhythmic burstingactivity that is synchronized between neighboring cells (Felleret al., 1996; Wong and Oakley, 1996; Wong, 1999). Calcium-imagingstudies showed that during the period of ON-OFF segregation, periodicelevations in intracellular calcium levels occurred much morefrequently in OFF cells compared with ON cells. This differencein mean activity levels, together with a decrease in synchronousactivity between the two cell types, can drive the ON and OFFsegregation process under a Hebbian model of synaptic competition(Lee and Wong, 1999). Because patterned activity in the RGCs ispotentially important for the refinement of retinogeniculate circuitry(Goodman and Shatz, 1993; Crair, 1999; Wong, 1999), we soughthere to determine the mechanisms that underlie the developmentalchange in the activity patterns of the ON and OFFRGCs.

First, we demonstrate that the difference in calcium activity patterns between maturing ON and OFF RGCs reflects differencesin spiking activity. This is important, because temporal informationrelevant for the segregation process is likely to be encoded inthe spike patterns. We then considered whether OFF cells may fireaction potentials more readily compared with ON cells for a givenexcitatory input, which would result in a relatively greater meanfiring rate in OFF cells. Next, because the circuitry of the innerretina matures during the ON-OFF segregation period (Sernagoret al., 2001), we examined whether differences in synaptic drivecontribute to a higher firing rate in OFF cells compared withON cells. It is possible that OFF RGCs become more active comparedwith ON RGCs at the older ages because OFF RGCs receive a greaternet excitatory drive. This could be attributable to OFF cellsreceiving a relatively stronger excitatory drive and/or weakerinhibitory drive. To investigate these possibilities, we comparedthe physiological properties and synaptic drives of morphologicallyclassified ON and OFF cells across two age groups, before andduring the period of ON-OFF axonal segregation, using whole-celland perforated-patch recordingtechniques.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Tissue preparation
Ferrets aged between postnatal day 7 (P7) and P24 were killed with 5% halothane followed by decapitation. The eyes were enucleatedand the retinas were separated from the pigment epithelium incold oxygenated Ames medium (Sigma, St. Louis, MO) that was bufferedwith 20 mM HEPES and titrated to a pH of 7.4 with 5 M NaOH. Eachretina was spread flat onto a glass slide, divided into two tofour pieces, and mounted ganglion cell side up on black filterpaper (HABP045; Millipore, Bedford, MA). The peripheral region(outer third) of the retina was positioned over a hole in thefilter paper, through which cells could be viewed and selectedforrecording.

Whole-cell and perforated-patch recordings
For all recordings, the extracellular solution was Ames medium (Ames and Nesbett, 1981). The retinas were maintained in oxygenatedmedia at room temperature until they were transferred to a recordingchamber. Perforated-patch and whole-cell recordings were performedat 32°C (Wong and Oakley, 1996; Wong et al., 2000a).
Perforated-patch recordings were performed using the cation-selective ionophore gramicidin D (Sigma) to gain electrical accessto the cell while maintaining the endogenous intracellular anioniccomposition. This configuration also minimizes the washout ofintracellular contents over time, and thus permits recording ofsodium action potentials over a much longer time, compared withwhat is possible with whole-cell recordings. The pipette solutionfor gramicidin perforated-patch recordings consisted of 119 mMKCl and gramicidin D (92.3 µg/ml) dissolved inmethanol.
Whole-cell voltage-clamp recordings were performed to measure excitatory and inhibitory synaptic currents. In the whole-cellconfiguration, we could isolate the excitatory synaptic inputsat a holding potential of $-$ 55 mV, the reversal potential for chloride.Inhibitory synaptic currents mediated predominantly by chloridechannels were isolated at a holding potential of 0 mV, the reversalpotential for the excitatory currents (Wong et al., 2000a). Forthese whole-cell voltage-clamp recordings, the pipette solutioncontained (in mM): 133 cesium gluconate, 10 TEA-chloride, 0.4MgCl₂, 10 NaCl, and 7 Na-HEPES. Cesium and TEA were included toblock voltage-gated potassium channels in the recorded cell andto facilitate the recording of synaptic inputs at positive holdingpotentials.
Whole-cell, current-clamp recordings were performed to measure spontaneous EPSPs. For these recordings, the composition ofthe recording (pipette) solution was similar to the endogenousion concentrations. It consisted of (in mM): 90 K-gluconate, 30KCl, 5 EGTA, and 10 Na-HEPES. For these experiments, lidocaineN-ethyl bromide (QX-314) (pipette concentration of 5 mM) was alsoincluded in this pipette solution to block sodium-dependent actionpotentials while recording the membrane potential. The QX-314current-clamp recordings enabled us to measure the amplitudesof the membrane depolarizations underlying the spikeactivity.
Drugs were applied using a gravity flow superfusion system. Unless otherwise indicated, all drugs were obtained from Sigma.The standard superfusate that was used to block excitatory andinhibitory inputs consisted of (in µM): 100 D-AP-5 (PrecisionBiochemicals, Vancouver, British Columbia, Canada), 20 1,2,3,4-tetrahydro-6-nitro-2,3-dioxobenzo[f]quinoxaline-7-sulfonamide(NBQX), 100 dihydro- $beta$ -erythroidin hydrobromide (DH $beta$ E), 150 picrotoxin,and 1strychnine.
Ganglion cells were viewed using a water immersion objective [63×, numerical aperature (N.A.) 0.9 Zeiss, Thornwood, NY] anda Nomarski optics filter on a Zeiss Axioskop fixed-stage microscope.To gain access to the cell bodies of ganglion cells, glial endfeetabove a selected cell were cleared with a patch pipette. The debriswas removed by suction through a patch pipette with a broken tip.All recordings were obtained using an Axopatch 200B amplifier(Axon Instruments, Foster City, CA). Electrodes were pulled fromborosilicate glass (TW150F-4; World Precision Instruments, Sarasota,FL) using a Flaming/Brown P-87 puller (Sutter Instruments, Novato,CA) and had resistances of 5-10 M $Omega$ . Membrane potentials were correctedfor junction potentials ( $-$ 5.3 mV for gramicidin solutions, $-$ 14.5mV for whole-cell voltage-clamp solutions, and $-$ 12.0 mV for whole-cellcurrent-clamp solutions). Series resistance was not compensated.Data were filtered at 2 kHz with the eight pole Bessel low-passfilter on the amplifier and digitized and stored on a Pentiumcomputer using a Labmaster data acquisition board (ScientificSolutions, Solon, OH). Spontaneous events were digitized and recordedon a digital audio tape recorder (PS75; Dagan, Minneapolis, MN).The sampling rate was 11 kHz. Patchit software (White Perch Software,Belmont, MA) was used to generate voltage and currentcommands.

Analysis
Voltage recordings. We defined long duration, sustained EPSPs as "sustained EPSPs." For voltage recordings in the presenceof QX-314, sustained EPSPs were identified by searching for localmaxima using MiniAnalysis (Synaptosoft, Leonia, NJ). An eventwas defined as a sustained EPSP if its amplitude was at least8 mV positive to the baseline membrane potential and its areawas >160 mVmsec. The baseline potential was obtained by averaginga 1 sec segment before the local maxima. When the algorithm occasionallyselected two candidate sustained EPSPs that overlapped, the longestduration event was classified as the sustained EPSP. The durationof a sustained EPSP was defined as follows. Its onset was thetime at which the voltage reached 0.5% of the peak amplitude andits offset was the time at which voltage returned to 1% of thepeak amplitude. Sustained EPSPs had durations of much longer than1 sec. Shorter duration EPSPs (called "transient EPSPs") occurredbetween the sustained EPSPs. An event occurring between sustainedEPSPs was defined as a transient EPSP if its amplitude was $>=$ 4mV positive to the baseline membrane potential. Transient EPSPshad durations of <0.5sec.
Current recordings. To identify and quantify sustained EPSCs and sustained IPSCs, we performed the following analysis in MatLab(MathWorks, Natick, MA). Candidate events were selected basedon their threshold amplitude above (IPSCs) or below (EPSCs) thebaseline membrane current. The onset and termination of each eventwere defined as the times when the current deviated from and returnedto baseline. Short-duration currents (called transient EPSCs and"transient IPSCs"), which occurred during the period between thesustained EPSCs and sustained IPSCs, respectively, were definedby MiniAnalysis as those events with amplitudes greater than fourtimes the root mean square of baselinenoise.

Morphological identification of ON and OFF RGCs
We focused our study on $beta$ RGCs that we had assessed previously by calcium imaging (Wong and Oakley, 1996). After recording,cells were classified morphologically as either ON or OFF $beta$ RGCsby intracellular filling with Lucifer yellow. The patch pipettescontained 0.01-0.02% Lucifer yellow. The dye diffused into thecell during whole-cell recording or after breaking through thecell membrane after perforated-patchrecording.
In the mature retina, physiologically classified OFF RGCs have dendritic arbors that stratify exclusively in sublamina a,whereas ON RGCs stratify in sublamina b of the inner plexiformlayer (IPL). Typically, sublamina b comprises the inner three-fifthsof the IPL and sublamina a comprises the outer two-fifths of theIPL (Nelson et al., 1978). Stratified $beta$ RGCs are present in theferret retina for both age groups included in our study (Wongand Oakley, 1996; Wang et al., 2001). Figure 1a is an exampleof a pair of P21 ferret $beta$ cells that were dye-filled with sulfurhodamine101 (1%; Molecular Probes, Eugene, OR); their dendritic arborswere clearly separated, ramifying in either sublamina a (OFF)or b (ON). The well-established relationship between dendriticmorphology and physiology holds true for the developing retina.In the ferret, when light responses can be first measured at P21,RGCs with dendrites stratifying in sublamina b (ON) increase theirfiring rates at light onset, whereas those cells stratifying insublamina a (OFF) increased their firing rates at light offset(Wang et al., 2001). The relationship between dendritic stratificationand ON or OFF responses also extends to RGCs which, during development,have yet to confine their dendrites to one sublamina (Bodnarenkoand Chalupa, 1993; Bodnarenko et al., 1995; Lohmann and Wong,2001). Unstratified RGCs have both ON- and OFF-center responses(Wang et al., 2001). It should be noted that before the thirdpostnatal week in ferrets, photoreceptors are not yet mature,and thus our classification of ON and OFF cells for the earlyage group (P7-P10) is based entirely on morphological criteria(Wong and Oakley, 1996; Bodnarenko et al., 1999).

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Figure 1. Dendritic stratification patterns of morphologically classified ON and OFF $beta$ RGCs. a, Top, Three-dimensional reconstruction of the arbors of morphologically defined ON and OFF $beta$ cells of a P21 ferret (see Materials and Methods). The stack of images was obtained at 0.25 µm step sizes from the base of the cell body using a two photon microscope (Zeiss 40× oil, N.A. 1.3) (1024M; Bio-Rad, Richmond, CA). Each image was acquired with 800 nm of excitation. Bottom, A 90° rotation of the image stack demonstrating the dendritic arbors of the ON and OFF RGCs ramifying in distinct sublaminas of the IPL. Sublaminas a (s_a) and b (s_b) are indicated. b, c, Epifluorescence image of Lucifer yellow labeling of a P21 $beta$ cell after whole-cell recording. Focusing from the base of the cell body (0 µm) at the IPL/ganglion cell layer border, the dendritic arbor of this cell was observed to terminate 6 µm into the IPL. We would classify this cell as an ON cell because its dendrites stratified within sublamina b. Scale bars, 10 µm.

To determine the stratification level of the recorded and dye-filled cells, we measured the depth of the dendritic arbor relativeto the inner and outer borders of the IPL. These borders weredetermined under transmitted light illumination and Nomarski opticsthat allowed us to assess the z-depth of the ganglion cell layer/IPLborder and the inner nuclear layer/IPL border. Both the ganglioncell and inner nuclear layers are easily distinguished under Nomarskioptics because they comprise only cell bodies. Simultaneous viewingof the Nomarski image and the fluorescent processes allowed usto define the location of the dendritic terminals relative tothe IPL borders. Z-depth was obtained in micrometers from thez-adjustment controls (1 µm steps) on the microscope stage (Fig.1b,c). Typically, in mid-peripheral retinas, the IPL was 20-22µm thick by the end of the first postnatal week and 23-25 µm intheadult.
In our recorded population, most cells had dendritic arbors confined to one sublamina; a smaller percentage had dendritesin both sublaminas (18% at P7-P10, n = 38; 1% at P18-P24, n =84). Only cells that stratified completely in the ON or OFF sublaminawere analyzed in detail, because we wanted to directly comparethe activity patterns of ON and OFF cells across ages. A totalof 19 ON cells and 12 OFF cells were recorded and analyzed forP7-P10, and 50 ON cells and 33 OFF cells were recorded and analyzedfor P18-P24.

Statistics
All summaries are means ± 1 SEM. Comparisons of the percentage of events above action potential threshold were made with az test in SigmaStat (SPSS, Chicago, IL). All other statisticalcomparisons were made with Mann-Whitney rank-sum tests in SigmaStat.Statistical significance was p < 0.05.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Patterns of spontaneous spike activity in developing ON and OFF RGCs

Our voltage recordings demonstrate that temporal patterns of spontaneous action potentials in ON and OFF RGCs alter with development.Figure 2a illustrates examples of the spike patterns of an ONand an OFF RGC from the early age group (P7-P10), recorded inperforated-patch mode. Both cell types generated periodic trainsof action potentials (Fig. 2a). The trains of action potentialsrode on sustained EPSPs.

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Figure 2. Spike patterns of developing ON and OFF RGCs. Perforated-patch recordings showing patterns of spontaneous spiking in ON and OFF RGCs at the younger (a) and older (b, c) ages are shown. The bottom traces in b and c are filtered versions of the raw data, revealing underlying sustained EPSPs of relatively long duration (asterisks in b) (see Materials and Methods). c, An example of a sustained EPSP from each of the two P21 cells in b shown at an expanded time scale. Note that there is little or no spiking before and after a sustained EPSP in the ON cell, but there is considerable spiking during these periods in the OFF cell.

The spike patterns of ON and OFF RGCs became distinct during the period when their axonal terminals segregate in the dLGN(P18-P24) (Fig. 2b). ON cells continued to rhythmically exhibitsustained EPSPs, with few or no action potentials between theseevents (Fig. 2b,c). In contrast, although OFF cells also periodicallydemonstrated sustained EPSPs and trains of action potentials,spiking occurred very frequently between the sustained events(Fig. 2b,c). The intervals between the sustained EPSPs for ONand OFF cells were not significantly different (Table 1).


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Table 1. Summary of time intervals between sustained events measured under different recording conditions for ON and OFF cells

We applied a mathematical filter (moving average function with a sampling window of 0.5 sec) to the raw voltage traces recordedfrom P18-P24 cells to define the duration of the sustained EPSPswithout interference from the action potentials. Figure 2b,c showsthat the filtering closely follows the shape and duration of theunderlying sustained EPSPs. This enabled us to compare the frequencyof spiking for ON and OFF cells during the sustained EPSPs andduring the periods between these events. For sustained EPSPs thatelicited action potentials, the average firing rate during thesustained EPSPs for ON cells was 1.70 ± 0.25 Hz, compared with4.12 ± 0.64 Hz for OFF cells. During the intervals between thesustained EPSPs, ON cells seldom spiked (average firing rate of0.01 ± 0.01 Hz), in contrast to OFF cells (0.52 ± 0.44 Hz). Overall,the mean spike rates were higher for OFF (1.17 ± 0.44 Hz) comparedwith ON (0.22 ± 0.03 Hz) cells. All differences in firing ratesbetween ON and OFF cells were significant (p < 0.02 for 16 ONcells and 6 OFFcells).

Action potential thresholds

We considered whether OFF cells could fire spikes more often compared with ON cells, because the OFF cells require less depolarizationto reach action potential threshold. To address this possibility,we recorded the firing patterns of ON and OFF RGCs in responseto a series of injected current steps. We compared the responsesof ON and OFF cells from the two age groups, before (P7-P10) andduring (P18-P24) ON-OFF segregation in the dLGN. Recordings wereperformed in perforated-patch mode in a cocktail of neurotransmitterreceptor antagonists (in µM: 100 D-AP-5, 20 NBQX, 100 DH $beta$ E, 150picrotoxin, and 1 strychnine) to block the inputs that contributeto spontaneous activity in the RGCs (Wong et al., 2000a).

We first compared the responses of ON and OFF RGCs to current injections at P18-P24. Resting potentials for ON and OFF cellsin Ames medium were $-$ 76.6 ± 1.6 mV (n = 24 cells) and $-$ 72.0 ±3.0 mV (n = 12 cells), respectively, which were not significantlydifferent. For a fixed-amplitude current injection, OFF cellsfired action potentials more readily (Fig. 3a). Figure 3b quantifiesthe firing rate during the duration of each current step for therecorded population. For a large range of current amplitudes (10-50pA), ON cells fired significantly fewer spikes than OFF cells.Next, we calculated the magnitude of depolarization required forON and OFF RGCs to reach their spike thresholds. The action potentialthreshold was defined as the potential at which the voltage maximallyaccelerated on the first evoked action potential (Fig. 3c). ONRGCs required 25 ± 3 mV, whereas OFF RGCs required only 15 ± 2mV to reach their respective action potential thresholds fromrest (Fig. 3d). Thus, OFF RGCs rest closer to their action potentialthresholds compared with ON RGCs, and relatively larger depolarizationsare required to evoke spiking in ON cells compared with OFF cells.

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Figure 3. Action potential thresholds of ON and OFF RGCs. Perforated-patch recordings from RGCs are shown. Voltage responses were recorded in a cocktail of receptor antagonists to block synaptic input. a, Depolarizing current steps, 800 msec in duration, were injected into the P18-P24 cells at the times indicated by the elevated horizontal lines below the traces. b, Mean firing rate ± SEM for the population of P18-P24 RGCs over the range of amplitudes of injected current. For each current amplitude, asterisks indicate a significant difference (p < 0.05) in the responses of ON compared with OFF RGCs. c, Example showing the voltage at which a spike is generated (the action potential threshold). d, The average ± SEM of the magnitude of depolarization [action potential threshold (Threshold) minus resting potential (V_rest)] required for ON (white bars) and OFF (black bars) cells to reach their respective action potential thresholds. The depolarization required to reach action potential threshold was significantly greater for ON compared with OFF RGCs for the P18-P24 age group (p = 0.02) but not for the P7-P10 group (p = 0.42). There was a significant decrease in the magnitude of depolarization required to reach threshold with increasing age in OFF RGCs (p = 0.005) but not in ON RGCs (p = 0.66). Recordings were from 10 ON cells and 6 OFF cells from P7-P10 and 8 ON cells and 7 OFF cells from P18-P24. Asterisks indicate statistically significant differences.

In contrast, at P7-P10, the amount of depolarization required to reach action potential threshold was similar for ON and OFF $beta$ RGCs (Fig. 3d). Interestingly, with age the magnitude of depolarizationrequired to reach spike threshold decreases in OFF cells but notin ON cells (Fig. 3d).

We also asked whether the difference in ON and OFF spike thresholds occurs at rest, when synaptic transmission is present.By recording and applying current steps in between the sustainedEPSPs, we found that the magnitude of depolarization requiredto reach spike threshold still differed significantly betweenON and OFF cells in the presence of tonic synaptic transmission(data not shown). Thus, a difference in spike threshold betweenON and OFF cells is likely to contribute to their disparate spikerates.

Spontaneous postsynaptic currents

To compare the properties of the inputs onto developing ON and OFF RGCs, we obtained whole-cell voltage-clamp records of theirspontaneous synaptic currents. To observe EPSCs, RGCs were voltageclamped at $-$ 55 mV, the chloride reversal potential set by thepipette and external solutions (see Materials and Methods). IPSCswere measured at a holding voltage of 0 mV, the reversal potentialdetermined previously for glutamatergic- and cholinergic-mediatedexcitatory currents (Wong et al., 2000a).

At P7-P10, we found that long-duration, periodically occurring EPSCs (sustained EPSCs) and IPSCs (sustained IPSCs) occurredin both ON and OFF RGCs (Fig. 4a). The sustained postsynapticcurrents (PSCs) resemble the compound EPSCs described previouslyin immature ferret ganglion cells (Feller et al., 1996) and rabbitganglion cells (Zhou, 1998; Zhou and Zhao, 2000). Both the sustainedEPSCs and sustained IPSCs occurred at a frequency similar to thatobserved for sustained EPSPs recorded in current-clamp mode (Table1). The average charge transfer (area under the current traces)of the sustained PSCs was not significantly different for ON andOFF RGCs (Fig. 5).

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Figure 4. Spontaneous currents in developing ON and OFF RGCs. Voltage-clamp recordings in whole-cell configuration of ON and OFF RGCs from the younger (a) and older (b) age groups are shown. Cells were voltage clamped at 0 mV (top trace of each pair, IPSCs) or at $-$ 55 mV (bottom trace of each pair, EPSCs). The scale bars in b apply to both holding potentials and to all cells shown in a and b. In both age groups and for ON and OFF cells, periodic, sustained EPSCs and IPSCs were observed. c, Transient EPSCs and IPSCs in older RGCs (indicated by asterisks).

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Figure 5. Quantification of sustained EPSCs and IPSCs of ON and OFF RGCs. Bars indicate the average ± SEM of the absolute value of the average charge transferred per sustained EPSC or sustained IPSC. At P7-P10, there were no significant differences in charge transfer per sustained EPSC or sustained IPSC between ON and OFF cells (p = 0.53 for IPSCs and EPSCs; 7 ON and 4 OFF RGCs). However, at P18-P24, OFF cells had larger charge transfer per sustained EPSC or sustained IPSC compared with ON cells (p = 0.003 for sustained IPSCs; p = 0.002 for sustained EPSCs; 5 ON and 8 OFF RGCs). Asterisks indicate statistically significant differences.

In the older age group (P18-P24), periodic sustained EPSCs and sustained IPSCs were also observed in ON and OFF RGCs (Fig.4b). The average charge transfer for both types of sustained eventswas greater in OFF compared with ON cells. This suggests thatfor a set driving force, both excitatory and inhibitory conductancechanges were larger in OFF cells compared with ON cells (Fig.5). However, the sustained EPSCs and IPSCs occurred at similarfrequencies for ON and OFF cells (Table 1). In addition to thesustained EPSCs and IPSCs, we also noted that in this older agegroup there were frequently occurring smaller amplitude and short-durationEPSCs and IPSCs in the ON and OFF RGCs (Fig. 4c). These transientEPSCs occurred at 1.1 ± 0.6 Hz (n = 4 cells) in ON cells and at6.4 ± 0.8 Hz (n = 6 cells) for OFF cells. The transient EPSC frequencywas significantly different between the ON and OFF cells (p =0.01). Transient IPSCs occurred at 1.8 ± 0.8 Hz for ON cells (n= 5 cells) and 7.6 ± 2.6 Hz for OFF cells (n = 6). Although thetransient IPSCs tended to occur at higher frequencies in the OFFcells, this was not significantly different from that of ON cells(p = 0.08).

Spontaneous postsynaptic potentials

We subsequently asked whether OFF cells may spike more frequently compared with ON cells because they receive a stronger netexcitatory drive. Although the amplitude of the PSCs differedbetween ON and OFF cells at P18-P24, the current recordings alonedo not reveal how the underlying excitatory and inhibitory conductancesact together to affect the membrane potential. In part, this isbecause the spontaneous excitatory and inhibitory events cannotbe easily observed and measured simultaneously during voltage-clamprecording. The perforated-patch, current-clamp experiments provideda reasonable estimate of the relative amplitudes of the EPSPsof ON and OFF cells (Fig. 2b), but this required low-pass filteringof high-frequency components to remove the spikes from the rawtraces. To directly measure the net depolarization resulting fromthe excitatory and inhibitory drives, we performed whole-cellvoltage recordings in the presence of QX-314, which diffuses intothe recorded cell and blocks its sodium actionpotentials.

Both ON and OFF RGCs showed sustained, periodic EPSPs resembling the depolarization pattern underlying the high-frequencyspiking shown in Figure 2 (compare Fig. 6 with Fig. 2b). The averageduration of the sustained EPSPs was significantly longer for theON cells than for the OFF cells (p = 0.015). For the ON cellsthe mean duration was 15.3 ± 1.1 sec (105 EPSPs from 11 cells),whereas for the OFF cells the mean duration was 11.6 ± 0.5 sec(92 EPSPs from 9 cells). The sustained EPSPs of ON and OFF RGCs,observed in the presence of QX-314, occurred at similar frequencies(Table 1). In both ON and OFF cells, transient EPSPs were alsodetected between the sustained EPSPs. The durations of the transientEPSPs were not different between the ON and OFF cells (p > 0.99).For ON cells the duration of the transient EPSPs was 201 ± 12msec (917 EPSPs from 11 cells); for the OFF cells the durationwas 197 ± 6 msec (1814 EPSPs from 9 cells).

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Figure 6. Spontaneous EPSPs in maturing ON and OFF RGCs. Voltage changes were recorded in whole-cell configuration with QX-314 in the pipette to block action potentials. a, Examples of spontaneous EPSPs in an ON and an OFF RGC. The durations of the sustained EPSPs are indicated by the horizontal bars (see Materials and Methods). b, Examples of sustained EPSPs from the cells in a shown in an expanded time scale. Asterisks indicate the transient EPSPs between the sustained EPSPs.

To quantify and compare the EPSP properties of the ON and OFF cells, we plotted the areas under the EPSPs against their peakamplitudes (Fig. 7a). Two clusters were readily identified inthese plots by area, corroborating the presence of two major typesof EPSPs. The peak amplitudes of both the sustained and transientEPSPs were on average greater in OFF cells compared with ON cells(Fig. 7b,c) despite overlap in their respective distributions.To assess whether the peak amplitudes of the EPSPs were sufficientto cause spiking, we compared their amplitudes with the averagedepolarization required to reach action potential threshold inON and OFF cells (Fig. 7a, vertical lines). Events with amplitudesthat are greater than the depolarization required to reach actionpotential threshold (represented by symbols to the right of theappropriate bars in Fig. 7a) are likely to elicit spikes. Figure7a shows that whereas 33.3% of the sustained EPSPs in ON cellscan lead to spiking, only 0.8% of the transient EPSPs exceededthe spike threshold for these cells. Thus, for ON cells, spikingmay be limited because many of the EPSPs do not bring the cellabove spike threshold. For OFF cells, the majority (92.5%) ofthe sustained EPSPs would be expected to lead to spiking. In contrastto ON cells, a larger percentage (5.3%) of the transient EPSPsin OFF cells are sufficient to cause spiking.

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Figure 7. Quantitative comparison of EPSPs in maturing ON and OFF RGCs. a, For each EPSP that was >4 pA above baseline, its area versus its amplitude is plotted for the recorded populations of ON cells (11 cells, open symbols) and OFF cells (9 cells, filled symbols). The EPSPs forming the upper cluster (squares) consist of sustained EPSPs; the lower cluster (diamonds) consists of transient EPSPs that occur between the sustained EPSPs. The vertical lines mark the average and SEM of the amplitude of depolarization required to reach the respective action potential thresholds (AP Thresh) of ON (dotted vertical line) and OFF (thick solid vertical line) RGCs (Fig. 4). b, c, Cumulative amplitude plots for sustained EPSPs (b) and transient EPSPs (c) for ON cells (dotted lines) and OFF cells (solid lines). Both types of EPSPs are significantly smaller in amplitude in ON cells compared with OFF cells (p = 0.019 for sustained EPSPs; p < 0.001 for transient EPSPs).

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Developmental changes in the activity patterns of RGCs

Our results show that ON and OFF RGCs develop different rates of spontaneous action potential activity during the period whentheir axonal projections segregate in the dLGN. We have also shownthat RGCs are capable of generating higher spike rates with maturation,in agreement with previous studies (Skaliora et al., 1993; Rotheet al., 1999). With increasing age, OFF $beta$ RGCs spike more frequentlycompared with ON $beta$ RGCs. This age-related change in the relativespike rates of ON and OFF RGCs is also observed for $alpha$ cells, anothermajor RGC class, as shown by calcium-imaging studies (for review,see Wong, 1997) and extracellular recordings from cell pairs (Leeand Wong, 1999). Thus, the divergence in spike patterns observedin $beta$ RGCs is not unique to this cell class but rather is a developmentalfeature characteristic of ON and OFF subtypes ofRGCs.

Although ON and OFF $beta$ RGCs develop different spike patterns with maturation, we did observe similarities in their activitypatterns even in the older age group. At P18-P24, both ON andOFF $beta$ cells exhibit sustained spontaneous EPSPs. Two observationssuggest that the periodically occurring sustained EPSPs representsynchronized activity among neighboring cells. First, the timeintervals between sustained EPSPs are similar for ON and OFF RGCsacross age groups (Table 1). These intervals, ~1-2 min, are similarto the intervals between spontaneous retinal waves that are knownto coordinate the activity of neighboring RGCs (for review, seeWong, 1999). Second, simultaneous calcium imaging and voltagerecordings show that sustained EPSPs occur when many cells inthe field of view exhibit an elevation in intracellular calciumlevels (K. Myhr and R. Wong, unpublished data). Thus, it is likelythat the sustained EPSPs of ON and OFF RGCs at P18-P24 are drivenby the lateral network underlying retinal waves (Wong, 1999).Transient EPSPs are also observed in P18-P24 ON and OFF $beta$ RGCs.These EPSPs may instead reflect the emergence of the photoreceptor-bipolarpathway that develops after the second postnatal week (Milleret al., 1999; Wang et al., 2001). Indeed, OFF RGCs may demonstratea higher frequency of spiking compared with ON RGCs because OFFbipolar cells are relatively more depolarized in the dark (Werblinand Dowling, 1969).

Mechanisms underlying the differences in ON and OFF spike patterns

We observed a fundamental difference in the intrinsic ability of ON and OFF cells to fire action potentials during ON-OFFsegregation in the dLGN. OFF cells rest closer to their actionpotential threshold compared with ON cells and respond with ahigher firing rate for a fixed-amplitude current input. What couldunderlie these differences in the excitability of ON and OFF cells?One possibility is that with maturation OFF cells express a greaterdensity of sodium channels than ON cells. Although many studieshave shown that RGC sodium channel expression increases with development(Skaliora et al., 1993; Schmid and Guenther, 1996; Rothe et al.,1999), comparisons between ON and OFF cells have not been undertaken.It is also possible that ON and OFF cells differ in the kineticsof their sodium channel inactivation rather than in their channeldensity. Wang et al. (1997) showed that the speed of recoveryfrom inactivation of the sodium current in rat RGCs increasedwith age and with increasing excitability of these cells. Althoughsuch kinetics can vary with RGC class in the adult retina (Kanedaand Kaneko, 1991), possible differences between ON and OFF RGCshave yet to be examinedsystematically.

Differences in potassium channel expression could also contribute to differences in spike rates and patterns (Hille, 1992).In the more mature ferret retina (P30-P45), relatively sustainedfiring can be converted to burst-like activity when calcium-activatedpotassium conductances sensitive to apamin are pharmacologicallyblocked (Wang et al., 1998). Interestingly, in that study, a subsetof $alpha$ and $beta$ RGCs was found to be insensitive to apamin. The morphologicalidentity of this subset is as yet unknown, but it may exclusivelycomprise ON or OFF RGCs. It may also be possible that immatureON and OFF $beta$ RGCs have similar densities and types of non-calcium-dependentvoltage-gated potassium channels that change with development(Skaliora et al., 1995; Rothe et al., 1999). Future experimentsdetermining the developmental profiles of sodium and potassiumchannel expression and kinetics in identified ON and OFF cellswould be highly informative with regard to their contributionto the distinct firing patterns of these celltypes.

In addition to differences in intrinsic excitability, we found that the synaptic drives onto P18-P24 ON and OFF RGCs are alsodifferent. In this age group, recordings in the presence of QX-314showed that the amplitudes of spontaneous sustained EPSPs areon average larger for OFF cells compared with ON cells. The relativelylarger sustained EPSPs in OFF cells may result from a strongerexcitatory drive. Consistent with this, our current recordingsindicated that sustained EPSCs were significantly larger in OFFcells compared with ON cells. These currents were shown previouslyto be glutamate-mediated for the older age group, suggesting acontribution from bipolar cell inputs (Wong et al., 2000a).

In the older age group, sustained IPSCs were also significantly greater in amplitude in OFF cells compared with ON cells:The Cl conductance changes of P18-P24 OFF cells were larger than thoseof ON cells. In conducting our experiments in whole-cell mode,we abolished any endogenous differences in [Cl]_i in the P18-P24 ON and OFF cells. Such a difference in endogenous[Cl]_i between ON and OFF cells may exist, as has been shown for neighboringneurons in the developing spinal cord (Rohrbough and Spitzer,1996). An uncertainty in endogenous chloride driving forces suchas this would make it difficult to determine in which directionthe chloride-mediated inputs contributed to the voltage responses.More likely, however, the larger IPSCs in OFF cells may simplyreflect larger GABA-mediated synaptic inputs. We could not determinethe timing of excitatory and inhibitory inputs, which interactto give rise to the sustained EPSPs. However, because the sustainedEPSPs were larger in OFF cells compared with ON cells, the netexcitatory drive must be greater in OFFcells.

Together our observations suggest that the intrinsic excitability and synaptic drive onto ON and OFF cells alter with ageand act together to shape the firing patterns of these cells.An intriguing question to pursue is how these mechanisms are developmentallyregulated to produce spike patterns of ON and OFF RGCs that areappropriate for the activity-dependent refinement of their axonalprojections.

Developmental implications of diverging ON and OFF RGC activity

The dendrites of RGCs also undergo reorganization and stratify into one of the two major sublaminas within the IPL duringthe period of ON-OFF axonal segregation (Bodnarenko et al., 1999;Lohmann and Wong, 2001). The dendritic stratification processmay also depend on spontaneous activity. Before vision, blockadeof glutamatergic transmission in the developing retina perturbsthe dendritic stratification patterns of ON and OFF RGCs (Bodnarenkoand Chalupa, 1993; Bodnarenko et al., 1995). Moreover, neurotransmissionregulates dendritic remodeling in both ON and OFF RGCs duringthe period of synaptogenesis and dendritic stratification (Wongand Wong, 2000; Wong et al., 2000b). Unstratified RGCs in theolder age group receive both ON and OFF bipolar inputs (Wang etal., 2001). Thus, dendritic remodeling in RGCs and the subsequentloss of one type of bipolar input may involve competition betweenON and OFF bipolar cells and possibly a process driven by differencesin their spontaneous and light-evoked activity patterns. In thepresent study, we did not compare the spike patterns of unstratifiedRGCs with those of well-stratified RGCs because we encounteredonly one unstratified cell at P18-P24. It would be interestingin the future to determine the spontaneous spike patterns of theseunstratified RGCs to elucidate the physiological properties ofthe "transiently present" bipolar inputs and to determine howthese inputs are eliminated as the ON and OFF pathways segregatewithin theretina.

Although it is clear that with age ON and OFF RGCs are contacted by synaptic inputs with different properties, these RGC subtypesalso appear to be intrinsically different. We demonstrated recentlythat the dendrites of ON and OFF RGCs form dendrodendritic contactsonly between cells of the same subtype, thus implying that thesetwo populations of cells possess distinct cell-to-cell recognitioncues (Lohmann and Wong, 2001). Our physiological recordings herelend additional support to the existence of molecular differencesbetween ON and OFF RGCs; with development, we found that ON andOFF RGCs exhibit different intrinsic membraneproperties.

In summary, our results demonstrate how the spike patterns of ON and OFF RGCs are developmentally regulated to convey informationrelevant for the activity-dependent refinement of their connectionswith dLGN neurons at each stage of development. The challengeremains for us to ascertain how in the visual system and in otherneural networks patterned spike activity and molecular differencesact in concert to set up precise connectivity patterns withmaturation.

  FOOTNOTES

Received May 3, 2001; revised July 26, 2001; accepted Aug. 15, 2001.

This work was supported by the National Institutes of Health. We thank the members of the Wong laboratory and Ken Tovar forinsightful discussions and critical reading of themanuscript.
Correspondence should be addressed to Dr. Rachel O. L. Wong, at the above address. E-mail: wongr{at}thalamus.wustl.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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