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The Journal of Neuroscience, June 15, 2001, 21(12):4310-4317
Unique Functional Properties of On and Off Pathways in the Developing Mammalian Retina
Guo-Yong Wang, Lauren C. Liets, and Leo M. Chalupa Section of Neurobiology, Physiology, and Behavior, Division of Biological Sciences and Ophthalmology Department, School of Medicine, University of California, Davis, Davis, California 95616
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
In the mature retina, the dendrites of On and Off ganglion cells are segregated into separate sublaminas of the inner plexiform layer, but early in development these processes are multistratified, ramifying more widely within this synaptic layer. The dendritic pattern exhibited by immature ganglion cells suggests that there may be a functional convergence of On and Off pathways in the developing retina, but previous studies have provided evidence against this. Here we demonstrate by patch-clamp recordings and dye filling that ganglion cells with multistratified dendrites respond to the onset, as well as the offset, of light. We further show that, in the dark-adapted retina, the glutamate analog 2-amino-4-phosphonobutric acid abolishes On and Off discharges in ganglion cells with multistratified dendrites. In contrast, in cells with stratified dendrites, this drug selectively blocks On responses. These findings provide evidence for unique functional attributes of On and Off pathways in the developing retina. The properties of immature ganglion cells documented here have important implications for the roles ascribed to neuronal activity in refining connections during the early development of the visual system.
Key words: development; retinal ganglion cell; APB; dendritic stratification; On and Off pathways; retina; visual system
INTRODUCTION
The pathways that signal light increments are segregated from those that signal light decrements in the mature retina. Thus, the axons of On-cone and Off-cone bipolar cells terminate in two distinct strata of the inner plexiform layer (IPL) in which they form synapses with the dendrites of On and Off retinal ganglion cells (Famiglietti and Kolb, 1976
; Nelson et al., 1978
To explain how synaptic activity could regulate the stratification of ganglion cell dendrites, a model was formulated stipulating that On- and Off-cone bipolar cell axons selectively innervate the multistratified dendrites of immature ganglion cells (Bodnarenko et al., 1995
Treating the developing retina with APB perturbs the stratification of On and Off retinal ganglion cells to an approximately equal degree (Bodnarenko and Chalupa, 1993
MATERIALS AND METHODS
Retinal preparation. Retinas were obtained from ferrets (Marshall Farm USA, North Rose, NY) ranging in age from postnatal day 21 (P21) to P55, with the day of birth denoted as P0. All animals were dark-adapted overnight before the recordings. After a lethal dose of barbiturate (Nembutal, 200 mg/kg, i.p.), the eyes were removed and placed in oxygenated L15 medium at 37°C for 12 min. The retinas were then carefully peeled from the eyecup and stored at room temperature in Eagle's minimal essential medium (EMEM), continuously bubbled with 95% oxygen and 5% CO2. A small piece of retina was placed ganglion cell layer up in the recording chamber and stabilized with an overlying piece of filter paper. A 2 mm hole in the filter paper provided access for the recording electrode. Cells were visualized through a 40× objective mounted on a fixed-stage upright epifluorescence microscope (Nikon, Tokyo, Japan). Infrared goggles were used to visualize the tissue on the dissecting and recording microscopes and to maneuver in the recording room. Light-emitting diodes (LEDs) (850 nm) were used to provide light to the dissecting microscope while the illumination from the recording microscope was passed through an
850 nm cut filter.
During recordings, the retina was perfused continuously with EMEM (1.5 ml/min) through a gravity-fed line, heated with a Peltier device, and continuously bubbled with 95% oxygen and 5% CO2. A calibrated thermocouple monitored the temperature in the recording chamber, maintained at 35°C. Recordings from individual cells usually lasted 30-120 min, and retinal segments from which recordings were made typically remained viable for 8-12 hr. Patch electrodes were filled with a solution containing 140 mM KCl, 10 mM HEPES, 0.5 mM EGTA, 0.5 mg/ml nystatin, 2.5 mg/ml Pluronic-F68, and 0.5% Lucifer yellow, pH 7.4. By the end of the experiment, the soma and the dendritic arborizations were usually completely filled, suggesting that recordings were made in the whole-cell configuration. Once complete cell filling was achieved, the retina was removed and fixed in 4% paraformaldehyde for 6-8 hr at 4°C.
Morphological analysis. Recorded cells were visualized and identified as ganglion cells before the electrode was withdrawn, and only neurons unequivocally identified as retinal ganglion cells were included in this study. Such identification was made on the basis of the morphological properties described by Wingate et al. (1992)
Electrophysiology. Patch pipettes with a tip resistance between 3 and 7 M
were pulled from thick-walled 1.5-mm-outer diameter borosilicate glass on a Sutter Instruments (Novato, CA) puller (model P-97). Current-clamp recordings were made with an Axopatch 200B patch-clamp amplifier (Axon Instruments, Foster City, CA). The data were low-pass filtered at rates between 1 and 2 kHz and digitized at rates between 1 and 4 kHz before storage on an IBM computer for subsequent off-line analysis. Recordings were obtained by patching onto cells with clear, nongranular cytoplasm. High-resistance seals were obtained by moving the patch electrode onto the cell membrane and applying gentle suction. After formation of a high-resistance seal between the electrode and the cell membrane, transient currents caused by pipette capacitance were electronically compensated by the circuit of the Axopatch 200B amplifier. If, during the recording, the seal resistance dropped below 1 G
Light stimulus. Light-evoked responses were obtained by delivering spots of light from three computer-controlled LEDs (having
d = 463, 569, and 651 nm) through the camera port. Spectral power was measured with a silicon photodiode and linear readout system (81 Optometer; United Detector Technology, Hawthorne, CA) and a spectroradiometer-photometer (PR703-A; Photo Research, Chatsworth, CA) scanning from 390 to 720 nm in 2 nm steps. These instruments were calibrated relative to standards of the National Institute of Standards and Technology. The number of quanta delivered to the retina was specified per receptor per second, assuming that the inner segments form the optical aperture (based on a diameter of 0.315 µm) (Weidman and Greiner, 1984
APB application. APB (25-100 µM) was dissolved in EMEM and administrated to the retinal whole mount through a gravity-fed line, heated with a Peltier device, and continuously bubbled with 95% oxygen and 5% CO2. A six-position rotary valve (Western Analytical Products, Murrieta, CA) was used to switch between bath and APB solutions. The APB perfusion normally lasted 20-30 min, and the washout lasted 40-60 min.
Data analysis. Response latencies were measured from the onset or the offset of the light stimulus to the onset of membrane depolarization giving rise to the spike discharges. The peak firing rate was calculated by counting the number of spikes within a window that encompassed the highest firing rate and dividing the spike number by the duration of the window.
RESULTS
Light responses of morphologically identified developing retinal ganglion cells
Whole-cell patch-clamp recordings were made from 151 ganglion cells of dark-adapted ferret retinas ranging in age from P21 to P55. This carnivore is born in a relatively immature state, ~42 d after conception, with eye opening normally occurring at P32. Thus, our earliest recordings were made 11 d before eye opening. This is well after the period of naturally occurring ganglion cell death (Henderson et al., 1988
At all ages, the responses evoked by a flashing spot of light centered on the soma were brisk and reliable when a sufficient interval was allowed between stimulus presentations, usually 30-60 sec. At shorter interstimulus intervals, responses tended to rapidly decrease in magnitude with repeated stimulation.
Three types of response patterns were observed. Some cells discharged only to light onset, others only to light offset, whereas a third group yielded both On and Off responses. These three patterns are illustrated for different cells in Figure 1. As may by seen, bursts of action potentials were superimposed on a prolonged depolarization of the membrane potential after the onset and/or the cessation of the stimulus. For a given cell, the response pattern was invariant over the scotopic range of stimulus intensities (9-174 quanta per receptor per second) used in this study.
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Figure 1. Whole-cell current-clamp recordings from three different ganglion cells in dark-adapted retinas. Light-evoked responses were obtained by delivering spots of light from three computer-controlled LEDs through the camera port. Three distinct response patterns were recorded: (1) On response, the cell responded only to light onset (top); (2) Off response, the cells responded only to light offset (middle); and (3) On-Off response, the cells responded to both light onset and offset (bottom). Recordings were made at 35°C. The ages for these three cells were P32, P30, and P34, respectively.
Although reliable responses were observed at all ages studied, there were significant increases in responsiveness with maturation. Age-related changes in response latency, defined as the time between stimulus onset or offset and the first spike in the response burst, as well as in average peak frequency, are depicted in Figure 2. These two response measures, obtained before and after eye opening, have been grouped separately for the On cells and Off cells (top panel) and the On-Off cells (bottom panel). As shown in Figure 2, On and Off responses became shorter in latency and had higher average peak firing rates after eye opening. Interestingly, the latencies of Off responses were significantly longer than those of On responses before and after eye opening. Presumably, this reflects the different circuitries of On and Off retinal pathways. Note that essentially the same pattern of results was obtained for the On and the Off cells as for the On-Off cells (compare top with bottom). Moreover, there were no significant differences in terms of response latency and average peak frequency between the On-Off cells and the cells that yielded only On or Off discharges.
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Figure 2. The latency and average peak firing rates of visual responses before and after eye opening are illustrated for On and Off cells (top), as well as for On-Off cells (bottom). Both latencies and average firing rates were significantly different before and after eye opening (*p < 0.05, two-tailed t test), with responsiveness increasing after eye opening. For all cell types, the latencies of the Off responses were significantly longer than those of the On responses (+p < 0.05, two-tailed t test).
Although all three types of cells (On, Off, and On-Off) were encountered at all ages studied, the incidence of On-Off cells was found to be age related. As may be seen in Figure 3, in the youngest age group (P21-P29), >70% of the recorded cells yielded On-Off discharges. A few days later (just after eye opening), the proportion of such neurons dropped to <50%. There was an additional decline in On-Off neurons over the next several weeks, so that in the oldest age group studied (P45-P55), such cells accounted for only ~12% of the sample. At all ages, the remainder of the recorded cells were either On or Off, with the former being more prevalent. In the entire sample, 57 cells were On-Off, 65 cells were On, whereas 29 cells were Off.
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Figure 3. Age-related changes in the percentage of On-Off retinal ganglion cells. Note that, at the earliest age studied, the majority of cells yielded On-Off discharge patterns and that the proportion of such cells decreased progressively with maturity. The numbers at the top of the bars indicate the On-Off cells over the total sample studied in each age group.
Filling neurons with Lucifer yellow allowed us to identify the classes of the recorded cells based on well established morphological criteria (Wässle and Boycott, 1991
,
, and
(Fig. 4). The majority were
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Figure 4. Recordings were made from three morphologically identified classes of ganglion cells:
When viewing individual cells, it often proved problematic to localize dendritic processes to a particular sublamina of the IPL without a clear reference point. This was resolved by labeling dopaminergic amacrine cells in the same sections that contained Lucifer yellow-filled ganglion cells. The dendrites of these amacrine cells stratify along the outer border of the IPL (Tagawa et al., 1999
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Figure 5. Stratification of developing ferret retinal ganglion cells. Cross-sections of two ganglion cells with stratified dendrites (top and middle) and one ganglion cells with multistratified dendrites (bottom) are shown. The red band is comprised of the dendrites of dopaminergic amacrine cells labeled with Texas Red, denoting the outermost extent of the IPL. The On cell (top) had dendrites that terminated proximal to the cell soma in the inner three-fifths of the IPL. The Off cell (middle) had dendrites that were confined to the outer two-fifths of the IPL, near the red band of dopaminergic amacrine cell dendrites. The multistratified cell (bottom) had dendrites that ramified more widely, spanning both sublaminas of the IPL. White lines indicate the borders of the On and Off sublaminas. Scale bar, 50 µm. Cells shown were from P42, P45, and P29 ferrets, respectively.
In the mature retina, the dendritic stratification pattern of a ganglion cell provides a "morphological signature" of the response pattern to a flashing spot of light (Famiglietti and Kolb, 1976
We were particularly eager to learn whether the On-Off cells were characterized by multistratified dendrites. The results show that this was indeed the case because cells with multistratified dendrites (25 of 32) commonly responded to both light onset and offset. Four such cells yielded only On responses and three others only Off responses. Of the 25 multistratified cells that yielded both On and Off discharges, one was an
We infer from these results that ganglion cells with multistratified dendrites are innervated early in development by On-cone and Off-cone bipolar cells. The finding that some ganglion cells with multistratified dendrites yielded only On or only Off responses could reflect the fact that one or the other cone bipolar cell input no longer formed functional synapses. Alternatively, dual innervation by cone bipolar cells may not be a universal property of all multistratified ganglion cells.
Effects of APB application on the visual responses of developing ganglion cells in the dark-adapted retina
We also characterized the functional properties of developing On and Off pathways by assessing the effects of APB on the discharge patterns of retinal ganglion cells. In the mature retina, this glutamate agonist hyperpolarizes On bipolar cells and rod bipolar cells, thereby preventing their release of glutamate (Slaughter and Miller, 1981
With respect to the cells with stratified dendrites, application of APB was found to differentially affect On and Off cells. Thus, in the dark-adapted retina, the responses of all On cells (n = 10) were blocked by application of this drug, whereas the responses of Off cells were resistant to APB (six of seven neurons). These observations indicate that, after segregation of On-Off retinal pathways has been established, the Off pathway is APB resistant, whereas the On pathway is sensitive to this glutamate analog.
In contrast, APB blocked both On and Off responses in multistratified ganglion cells. Thus, in 15 of 18 On-Off cells, all responses were abolished, whereas in three such cells, APB blocked On responses and reduced but did not entirely eliminate Off responses. This demonstrates that On, as well as Off, pathways are APB-sensitive in ganglion cells with multistratified dendrites. Examples of the effects of APB application on the responses of On, Off, and On-Off cells are shown in Figure 6.
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Figure 6. Whole-cell current-clamp recordings show the effect of APB on the light-evoked responses of ganglion cells in the dark-adapted retina. Immature cells yield On-Off responses (top traces) that were blocked by APB (25 µM). Likewise, the responses of On cells (middle traces) were also blocked by application of APB, even at low concentrations (25 µM). In contrast, Off cell responses (bottom traces) were resistant to application of APB, even at high concentration (100 µM). Light-evoked responses that were blocked by application of APB recovered when the drug was removed from the bath. Calibration: 1 sec, and 30 (top traces), 45 (middle traces), and 60 (bottom traces) mV. Recordings were made at 35°C. The ages for these three cells were P38, P42, and P50, respectively.
To determine whether the effects of APB application on the light-evoked responses of developing retinal ganglion cells varied with concentration of the drug, we tested a range of concentrations (25-100 µM) on all three cell types. The effect of APB on On responses was consistent across this range, with On responses being blocked at even the lowest concentration. Likewise, the On and Off responses of multistratified cells were also blocked at low concentrations of APB. Moreover, the light-evoked responses of Off cells were resistant to APB, even at the highest concentration tested (Fig. 6). These findings indicate that the effects of APB we observed cannot be explained by differential sensitivity of the different cell types to this drug. Rather, the results demonstrate the presence of an APB-sensitive Off pathway in the developing ferret retina that innervates multistratified ganglion cells.
DISCUSSION
Our results provide evidence for two unique functional properties of On and Off pathways in the developing retina. First, we have shown that multistratified ganglion cells in the immature retina respond to both light onset and offset. Most likely, this reflects the convergence of On- and Off-cone bipolar cells. Such response patterns were unexpected because previous studies concluded, on the basis of extracellular recordings, that very few ganglion cells in the developing cat retina respond to both the onset and offset of light (Dubin et al., 1986
It should be noted that we report a higher proportion of multistratified ganglion cells than previous studies on the developing ferret (Bodnarenko et al., 1999
A second unique functional feature of the developing retina was demonstrated by the changing susceptibility observed in the Off pathway to APB application. Although this drug blocked both On and Off responses of multistratified ganglion cells, in cells with stratified dendrites, APB selectively abolished On responses. Because our recordings were made from dark-adapted retinas, only the rods were capable of responding to light. Rods transmit signals via rod bipolar cells to all amacrine cells, then to On- and Off-cone bipolar cells (by gap junctions and glycinergic synapses, respectively), which in turn innervate the dendrites of On and Off ganglion cells (Sharpe and Stockman, 1999
Regulation of dendritic stratification by glutamate-mediated activity
Previously, we showed that intraocular injections of APB prevented the normal stratification of retinal ganglion cell dendrites (Bodnarenko and Chalupa, 1993
Electrophysiological recordings from mature animals that received intraocular injections of APB early in development have revealed the presence of many ganglion cells with On-Off responses (Bisti et al., 1998
Recently, Tagawa et al. (1999)
To explain how glutamate-mediated activity regulates the stratification of retinal ganglion cell dendrites, we proposed that an asymmetrical innervation of On- or Off-cone bipolar cells could "instruct" developing ganglion cells which dendritic process to retract and which to maintain (Bodnarenko et al., 1995
So how can one account for the role of afferent activity in the stratification of ganglion cell dendrites? One possibility is that glutamate release from bipolar cells triggers an intrinsic program in multistratified ganglion cells leading to the retraction of one or another set of their dendritic processes. This idea would be supported if it could be shown that the molecular composition of On and Off cells differs and that such differences are expressed in immature ganglion cells with multistratified dendrites. It may also be the case that signals from other types of retinal afferents contribute to this developmental event. In particular, it would be of interest to assess the impact of cholinergic inputs from amacrine cells because it has been shown that the processes of these retinal interneurons become stratified very early in development of the ferret retina (Feller et al., 1996
Implications for the role of activity in refinement of retinal projections
In the mature ferret, retinal projections are segregated in the dorsal lateral geniculate nucleus into eye-specific laminas, as well as On and Off sublaminas. The formation of eye-specific projections occurs within the first 2 postnatal weeks (Linden et al., 1981
To date, the studies dealing with the role of activity in the formation of retinal projection patterns have focused almost exclusively on "spontaneous" discharge patterns (Maffei and Galli-Resta, 1990
Our results also indicate that On-Off ganglion cells are prevalent in the developing retina during the time when On and Off retinogeniculate pathways are becoming segregated. Thus, the activity-mediated segregation of On and Off retinal inputs to the lateral geniculate nucleus would appear to reflect, at least during the initial phase, the contributions of a relatively limited subset of ganglion cells. As stratification of ganglion cell dendrites progresses, more cells could be recruited to this process, leading ultimately to the formation of segregated On and Off retinogeniculate inputs.
FOOTNOTES Received Feb. 5, 2001; revised March 21, 2001; accepted March 29, 2001.
This research was supported by National Institutes of Health Grant EY03991, National Science Foundation Grant IBN12593, and a Core grant from the National Eye Institute of the National Institutes of Health. We thank Cara J. Wefers for technical assistance and Dr. Jack Werner for measuring the intensity and background of the light stimuli.
G.-Y.W. and L.C.L contributed equally to this work.
Correspondence should be addressed to Leo M. Chalupa, Section of Neurobiology, Physiology, and Behavior, University of California, Davis, Davis, CA 95616. E-mail: lmchalupa{at}ucdavis.edu.
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[Abstract] [Full Text] [PDF]
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