Light-Evoked Excitatory and Inhibitory Synaptic Inputs to ON and OFF α Ganglion Cells in the Mouse Retina

Light responses of ONαGCs are mediated primarily by a cation current of mixed rod and cone inputs

Under infrared visual guidance in dark-adapted flat-mount mouse retinas, we selected ON ganglion cells, with large cell bodies that exhibited increased spike activity during light illumination with loose-patch electrodes. These cells were subsequently recorded with patch electrodes filled with internal solution and Lucifer yellow in the whole-cell voltage-clamp configuration. ONαGCs were identified by their three-dimensional morphology revealed by Lucifer yellow fluorescent images in retinal flat mounts and vertical sections (for details, see Materials and Methods). Figure 1, A and B, shows the stacked confocal fluorescent image of an ONαGC in the flatmount retina (A) and the image of the same cell in the vertical retinal section (B). The fluorescent images exhibited typical ONαGC morphology with dendrites stratifying near 70% of the IPL depth and a dendritic field of ∼257 μm. The dendrites of all 28 ONαGCs we studied stratified near 65–80% of the IPL depth, with field diameters ranging from 210 to 335 μm. Figure 1C shows the light-evoked current responses of the same cell to a 2.5 sec light step recorded under dark-adapted conditions at various holding potentials. ONαGCs exhibited two light-evoked current components at the light onset. The early component (the peak inward current, marked with ○ in the inset in D) reversed near +10 mV [close to the equilibrium potential of a cation channel (E_C), as determined by the reversal potential of glutamate-induced current in the presence of 2 mm Co²⁺ (data not shown)] and the late component (the peak outward current, marked with • in the inset in D) reversed near -60 mV [the equilibrium potential of the chloride channel (E_Cl); see Materials and Methods]. The current–voltage (I–V) relationships of these two current components (Fig. 1D) have positive slopes, indicating that they are associated with conductance increases. All 28 ONαGCs exhibited very similar response waveform, with the reversal potential of the early component ranging from -10 to 20 mV and that of the late component ranging from -46 to -61 mV. The average zero-current potential in darkness of these cells was -63 ± 6 mV (see Materials and Methods). Because ONαGCs in the mammalian retina received glutamatergic inputs from DBC_Cs and GABAergic–glycinergic inputs from amacrine cells (Pourcho and Owczarzak, 1989; Cohen et al., 1994; Qin and Pourcho, 1996; Brandstatter et al., 1998), the early component is likely to be mediated by bipolar cell inputs that gate a cation conductance, and the late component is likely mediated by amacrine cell inputs that gate a chloride conductance (Cohen and Miller, 1994).

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Figure 1.

ONαGC. A, Stacked confocal fluorescent image in the flat-mount retina; B, image of the same cell in the vertical retinal section. Scale bars, 20 μm. PRL, Photoreceptor layer; OPL, outer plexiform layer; INL, inner nuclear layer; GCL, ganglion cell layer. C, Light-evoked current responses to a 2.5 sec light step (500 nm; -3 = 700 Rh^*rod^-1sec^-1) at various holding potentials. D, Current–voltage relationships of the early (○) and late (•) component of the light responses. Spike activities (E), light-evoked excitatory cation current (ΔI_C) recorded at E_Cl (F), and light-evoked inhibitory chloride current (ΔI_Cl) recorded at E_C to 500 nm light steps (2.5 sec) of various intensities (G). H, Response–intensity relationships of the light-evoked cation and chloride currents [ΔI_C–Log I (○) and ΔI_Cl–Log I (•)]. The average dynamic range for ΔI_C is 4.9 log units and that for ΔI_Cl is 5.3 log units.

To determine the relative rod–cone contribution to the ganglion cell light responses, we examined the light sensitivity of ONαGCs to 500 nm light steps under dark-adapted conditions. We used 500 nm light because mouse rods and cones exhibit the largest sensitivity difference near this wavelength (Lyubarsky et al., 1999), making it easier to distinguish between the two photoreceptor inputs to ganglion cells. Additionally, previous work and our preliminary data from the mouse retina have provided response thresholds and dynamic ranges of rods, rod bipolar cells, some cone bipolar cells, and amacrine cells to 500 nm lights, as well as the relative cone–rod sensitivity (Table 1, top). The threshold of dark-adapted mouse rods for 500 nm light is ∼1.9 Rh^*rod^-1sec^-1 (Field and Rieke, 2002; Howes et al., 2002), and that of the M-cones is ∼25–100 times higher (Baylor, 1987; Schneeweis and Schnapf, 1995; Lyubarsky et al., 1999). Because all mouse cones contain the M-pigment and most cones contain the S-pigment of various proportions (Applebury et al., 2000), these cells may be approximately divided into M-dominated (M/s) and S-dominated (S/m) cones, and the S-pigment is ∼2 log units less sensitive to the 500 nm light than the M-pigment (Lyubarsky et al., 1999). The threshold of rod bipolar cells (DBC_R) in dark-adapted mouse retina is near 0.1–0.6 Rh^*rod^-1sec^-1 (Field and Rieke, 2002), with a dynamic range of ∼2.2 log units (Berntson and Taylor, 2000). The dynamic range of the M/s cone ON bipolar cell (DBC_MC) response is much wider (∼4 log units), and it consists of a rod input component with a response threshold near 1 Rh^*rod^-1sec^-1 (presumably mediated by rod–cone coupling and/or DBC_R–AII amacrine cell–DBC_C pathway) and a cone input component with a threshold ∼2 log units higher (Berntson and Taylor, 2000). We recorded from two HBC_Cs that were more sensitive to 360 nm light than to 500 nm light (data not shown), and thus we believe that they are S/m cone bipolar cells (HBC_SCs). The threshold of these cells for 500 nm light was ∼2000 Rh^*rod^-1sec^-1, and the dynamic range was 1.5 log units. We also recorded from seven AII amacrine cells (data are not shown but will be presented in a later publication), and the response threshold was ∼0.001 Rh^*rod^-1sec^-1 and the dynamic range was 3.7 log units.

By comparing the response thresholds and dynamic ranges of preganglion cells with those of the α ganglion cells, we determined what types of bipolar cells and amacrine cells mediate α ganglion cell light responses. Figure 1E–H shows the spike activities (E), light-evoked excitatory cation current (ΔI_C) recorded at E_Cl (F), and light-evoked inhibitory chloride current (ΔI_Cl) recorded at E_C (G) of the same ONαGC (as in Fig. 1A–D) to 500 nm light steps (2.5 sec) of various intensities. In darkness, the cell exhibited no observable spontaneous spikes. The -7 light step elicited no spike response but a very small ΔI_C, whereas the -6 (0.7 Rh^*rod^-1sec^-1) light step gave rise to a burst of spikes and an inward ΔI_C of ∼100 pA at E_Cl. As the light step became brighter, the spike train became longer and of higher frequency, and the inward ΔI_C became larger. We measured the light sensitivity of ΔI_C to 500 nm light in all 28 ONαGCs, and the average ± SD response–intensity (ΔI_C–Log I) relationsships are plotted in Figure 1H (○). The solid curve was fitted by the Hill equation (see Materials and Methods). The average threshold (defined as eliciting 5% of the maximum response) was near -7.2 (0.044 Rh^*rod^-1sec^-1), and the dynamic range was 4.9 log units. Our data demonstrate that the dynamic range and response threshold of ΔI_C in mouse ONαGCs are close to those of the DBC_MC (Table 1), which have mixed rod/M-cone signals [two limbs in the response intensity curve (Berntson and Taylor, 2000)], consistent with the idea that the primary light-evoked excitatory inputs in ONαGCs are mediated by the cone ON bipolar cells (Bloomfield and Miller, 1986; Bloomfield and Dacheux, 2001).

The average threshold of light-evoked inhibitory current ΔI_Cl of the 28 ONαGCs was -6.8 (0.1 Rh^*rod^-1sec^-1), and the average ± SD response–intensity (ΔI_Cl–Log I) relationship (shown in Fig. 1H, •) had an average dynamic range of 5.3 log units. This indicates that the amacrine cells mediating ΔI_Cl of ONαGCs have similar rod–cone signals (we named these cells AC_M1) as the DBC_MCs, with a slightly lower threshold and wider dynamic range. In all ONαGCs, the threshold of light-evoked spike activities (0.047 ± 0.005 Rh^*rod^-1sec^-1) was closer to that of the ΔI_C than to ΔI_Cl. This is consistent with our observation that the dark resting potential of the ONαGCs (-63 ± 6 mV) are very close to E_Cl, and thus the spiking signals of the cells are predominately mediated by ΔI_C from DBC_MC inputs. Average response thresholds and dynamic range as well as the dark membrane potentials of ONαGCs are listed in Table 1 (bottom).

Light-evoked chloride currents from amacrine cells shunt ONαGC light responses

Despite the homogeneity in the threshold and dynamic range of light-evoked spikes, ΔI_C and ΔI_Cl in all ONαGCs, the strength (amplitude) of ΔI_Cl varied from cell to cell. Figure 2A shows histograms of the peak ΔI_Cl amplitudes of 23 dark-adapted ONαGCs. The amplitude of ΔI_Cl in approximately one-half of the ONαGCs was <50 pA, whereas that of the other one-half was between 60 and 300 pA. There were no noticeable differences in the cell morphology, response sensitivity, ΔI_C amplitude, or I–V relationships between those cells with large ΔI_Cl and those with small ΔI_Cl. However, the frequency of light-evoked spikes in ONαGCs with small ΔI_Cl was consistently higher than that with larger ΔI_Cl. Figure 2B shows light-evoked current responses at different potentials in an ONαGC with small ΔI_Cl, and Figure 2C shows the spike responses to 500 nm light of different intensities. The ΔI_Cl measured at E_C = + 12 mV was ∼3 pA, and the spike activities of the cell exhibited the same threshold (-6.3) to 500 nm light as the cell in Figure 1 that had a larger ΔI_Cl; however, the cell displayed a higher spike frequency. Light-elicited spike frequency of the five ONαGCs with ΔI_Cl <10 pA was approximately two to five times higher than those ONαGCs with larger ΔI_Cl. This inverse relationship between spike frequency and ΔI_Cl suggests that an important function of amacrine cell (AC_M1) inputs (associated with a chloride conductance increase) to ONαGCs is to shunt the voltage responses elicited by ΔI_C from bipolar cell inputs. Variations of AC_M1 inputs result in a spectrum of light spike response frequencies in various ONαGCs.

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Figure 2.

ΔI_Cl amplitude and ONαGC responses. A, Histogram of ΔI_Cl amplitude of 23 ONαGCs; B, light-evoked current responses of an ONαGC (whose ΔI_Cl peak amplitude was 3 pA) to a 2.5 sec light step (500 nm; -3 = 700 Rh^*rod^-1sec^-1) at various holding potentials; C, the spike responses to 500 nm, 2.5 sec light steps of various intensities of the same cell.

Light responses of transient OFFαGCs are mediated primarily by a transient cation current from S-cone-driven bipolar cells

By using the same experimental procedures, we studied light responses of 32 OFF α ganglion cells. Two major types of OFF response patterns were observed, although the morphology of these cells was very similar. The first type was quiet in darkness (no spontaneous spikes), and they exhibited transient spike activities only at the cessation of the light step [we named these cells transient OFF cells (tOFFαGCs)], whereas the second type exhibited spontaneous spikes in darkness and a sustained reduction of spike activity during the light illumination [we named these cells sustained OFF cells (sOFFαGCs)]. Among the 32 OFF α-like ganglion cells from which we recorded, 12 showed tOFFαGC responses and 20 displayed sOFFαGC responses.

Figure 3A–D shows the stacked confocal fluorescent image of a tOFFαGC in the flat-mount retina (A), the image of the same cell in vertical retinal section (B), the light-evoked current responses to a 2.5 sec 500 nm light step recorded under dark-adapted conditions at various holding potentials (C), and the current–voltage relationships of the responses at light onset and offset (D). The fluorescent images in A and B exhibited typical OFF α-cell-like morphology with dendritic field diameter ranging from 180 to 250 μm, and dendrites stratified near 30% (instead of 70% in the ONαGCs) of the IPL depth (Peichl, 1989; Doi et al., 1995). The baseline currents at -60 mV or below were very smooth, except for a few small transient inward current bumps [spontaneous EPSCs (sEPSCs)] mediated by spontaneous release of glutamatergic vesicles (Tian et al., 1998). The baseline currents at -40 mV or above, however, were much noisier, with many transient outward currents [spontaneous IPSCs (sIPSCs)]. This abrupt voltage-dependent increase of sIPSCs occurred between -40 and -60 mV and was consistent in all OFF α ganglion cells (both tOFFαGCs and sOFFαGCs; see below). At negative holding potentials (-60 to -100 mV), the light step elicited small outward current responses at the onset and a large transient inward current at the offset. The ON response became larger at more positive potentials, and it did not exhibit a reversal potential between -100 and +60 mV, suggesting that it may be mediated by two opponent conductance changes: a cation conductance decrease at the HBC–tOFFαGC synapse and a chloride conductance increase at the AC–tOFFαGC synapse. The OFF response was a transient inward current at negative potentials, it became smaller as the holding potential became more positive, and it reversed near +20 mV (E_C). All 12 tOFFαGCs exhibited very similar baseline noise and ON and OFF light responses with the E_C values for the OFF response varying from -10 to +25 mV. The average zero-current potential in darkness of these cells was -61 ± 7 mV. These results suggest that the OFF response of the tOFFαGC is probably mediated by a cation conductance (with reversal potential near 0 mV), a mechanism that is consistent with anatomical results, suggesting that OFF α ganglion cells in mammalian retinas receive synaptic inputs from the OFF cone bipolar cells (HBC_Cs) (Bloomfield and Dacheux, 2001).

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Figure 3.

tOFFαGC. A, Stacked confocal fluorescent image in the flat-mount retina; B, image of the same cell in the vertical retinal section. Scale bars, 20 μm. PRL, Photoreceptor layer; OPL, outer plexiform layer; INL, inner nuclear layer; GCL, ganglion cell layer. C, Light-evoked current responses to a 2.5 sec light step (500 nm; -2 = 7000 Rh^*rod^-1sec^-1) at various holding potentials; D, current–voltage relationships of the ON (○) and OFF (•) responses. Spike activities (E), light-evoked excitatory cation current (ΔI_C) recorded at E_Cl (F), and light-evoked inhibitory chloride current (ΔI_Cl) recorded at E_C to 500 nm light steps (2.5 sec) of various intensities (G). H, Response–intensity relationships of the light-evoked cation and chloride currents [ON ΔI_C–Log I (○), OFF ΔI_C–Log I (•), and ON ΔI_Cl–Log I (▴)]. The average dynamic range for ON ΔI_C is 3.9 log units, that for the OFF ΔI_C is 1.6 log units, and that for ΔI_Cl is 3.3 log units.

Figure 3E–G shows the spike activities (E), ΔI_C (F), and ΔI_Cl recorded at E_C (G) of a tOFFαGC to 500 nm light steps (2.5 sec) of various intensities. In darkness, the cell exhibited no observable spontaneous spikes but some sEPSCs. The -5 step elicited no spiking activities and a very small ON ΔI_C, whereas the -4 and -3 light steps evoked no spikes and larger outward ON ΔI_C. Brighter light steps (-2 and -1) elicited a brief train of spikes and a transient OFF inward ΔI_C, in addition to the outward ON ΔI_C. We measured the light sensitivity of OFF ΔI_C to 500 nm light in all tOFFαGCs, and the average ± SD response–intensity (OFF ΔI_C–Log I) relationships are plotted in Figure 3H (•). The solid curve was fitted by the Hill equation. The average threshold was near -2.7 (1394 Rh^*rod^-1sec^-1), and the dynamic range was 1.6 log units. The average spike response threshold was 1813 ± 470 Rh^*rod^-1sec^-1, indicating that the spike response of these cells are mediated by the OFF ΔI_C. Because the OFF ΔI_C and spike response threshold and dynamic range are very close to those of the HBC_SCs (Table 1), we believe that they are primarily mediated by the S/m cones through the S/m cone hyperpolarizing bipolar cells.

“Silent” bipolar cell inputs to tOFFαGCs at light onset

The threshold of the ON ΔI_C (Fig. 3F,H, ○) was approximately -5, which was ∼2–3 log units higher than that of the OFF ΔI_C and spike responses. We measured the light sensitivity of ON ΔI_C to 500 nm light in all 12 tOFFαGCs, and the average ± SD response–intensity (ON ΔI_C–Log I) relationship is plotted (and fitted by the Hill equation) in Figure 3H (○). The average threshold was near -5.8 (1.1 Rh^*rod^-1sec^-1), and the average dynamic range was 3.9 log units. By comparing these results with the parameters listed in Table 1, we believe that the ON ΔI_C of tOFFαGCs is mediated primarily by HBC_MCs. It is important to note that ON ΔI_C is an outward current that results in membrane hyperpolarization and decrease of spike activity. Therefore, because tOFFαGCs do not exhibit spontaneous spike activities in darkness (Fig. 3E), ON ΔI_C cannot decrease spiking further, and thus it has no physiological consequences on the tOFFαGC output and can be considered as a silent bipolar cell input.

Silent amacrine cell inputs to tOFFαGCs

The average threshold of ΔI_Cl elicited by 500 nm light from 12 tOFFαGCs was -5.5 (2.2 Rh^*rod^-1sec^-1), and the average ± SD response–intensity (ΔI_Cl–Log I) relationships (Fig. 3H) had a dynamic range of 3.3. Comparing these results with the parameters listed in Table 1 reveals that the ΔI_Cl of tOFFαGCs is probably mediated by amacrine cells with mixed rod and cone inputs (we named these cells AC_M2, which receive inputs from M-cone bipolar cells with mixed rod) [possibly through rod–cone coupling and/or AII amacrine cells (Demb and Pugh, 2002)] and M-cone inputs. Because the average zero-current potential in darkness of these cells was -61 ± 7 mV, a value very close to E_Cl, the AC_M2-mediated current response (ΔI_Cl) contributes little to the total light-evoked current. Moreover, because tOFFαGCs do not exhibit spontaneous spike activities in darkness (Fig. 3E) and ΔI_Cl returns to the baseline before the onset of the transient inward OFF ΔI_C (Fig. 3F,G; for shorter light stimuli, OFF ΔI_C was much smaller), the shunting action of ΔI_Cl-mediated conductance increase causes little physiological consequence to the tOFFαGC output and can be considered as a silent amacrine cell input.

Average response thresholds and dynamic range as well as the dark membrane potentials of ON ΔI_C, OFF ΔI_C, and ΔI_Cl of the tOFFαGCs are listed in Table 1 (bottom).

Light responses of sOFFαGCs are mediated by both a cone-driven bipolar cell input and a rod-driven amacrine cell input

Figure 4A–C shows the stacked confocal fluorescent image of a sustained sOFFαGC in the flat-mount retina (A), the image of the same cell in vertical retinal section (B), and the light-evoked current responses to a 500 nm 2.5 sec light step recorded under dark-adapted conditions at various holding potentials (C). The fluorescent images in A and B exhibited typical OFF α ganglion cell morphology with dendrites stratified near 30% of the IPL depth (Peichl, 1989; Doi et al., 1995). Similar to the tOFFαGCs, the baseline currents at -60 mV or below were relatively smooth and at -40 mV or above were much noisier, possibly attributable to electrical coupling with amacrine cells that release GABAergic or glycinergic vesicles onto the recorded cell (Xin and Bloomfield, 1997) (see Discussion). The light step gave rise to a transient outward current followed by a sustained outward current at all potentials (without a reversal potential), and the current–voltage relationships of the peak and steady-state light responses are shown in Figure 4D. The lack of reversal potential suggests that the light response is probably mediated by two opponent conductance changes, a cation conductance decrease at the HBC–sOFFαGC synapse and a chloride conductance increase at the AC–sOFFαGC synapse. The sustained outward current lasted for seconds after light offset and then exhibited one to two transient dips (Fig. 4C). All 20 sOFFαGCs exhibited very similar baseline noise and light response patterns, and the average zero-current potential in darkness of these cells was -51 ± 7 mV. A major difference between the tOFFαGCs and sOFFαGC is that sOFFαGCs did not show the transient inward current at light offset (compare Figs. 3C, 4C).

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Figure 4.

sOFFαGC. A, Stacked confocal fluorescent image in the flat-mount retina; B, image of the same cell in the vertical retinal section. Scale bars, 20 μm. PRL, Photoreceptor layer; OPL, outer plexiform layer; INL, inner nuclear layer; GCL, ganglion cell layer. C, Light-evoked current responses to a 2.5 sec light step (500 nm; -2 = 7000 Rh^*rod^-1sec^-1) at various holding potentials; D, current–voltage relationships of the peak (○) and steady-state component (•) of the light responses. Spike activities (E), light-evoked excitatory cation current (ΔI_C) recorded at E_Cl (F), and light-evoked inhibitory chloride current (ΔI_Cl) recorded at E_C to 500 nm light steps (2.5 sec) of various intensities (G). H, Response–intensity relationships of the light-evoked peak cation and chloride currents [ΔI_C–Log I (○) and ΔI_Cl–Log I (•). The average dynamic range for ΔI_C is 3.0 log units, and that for ΔI_Cl is 5.9 log units.

Figure 4 E–H shows the spike activities (E), ΔI_C (F), and ΔI_Cl (G) of the same sOFFαGC as in Figure 4 A–D to 500 nm light steps (2.5 sec) of various intensities. In darkness, the cell exhibited spontaneous spikes of ∼5–10 Hz and some sEPSCs at E_Cl. The -8 step resulted in a very brief period of decrease in spiking activities, elicited no ΔI_C, but evoked a sustained outward ΔI_Cl. The -7 light step decreased the spike frequency for ∼0.7 sec, elicited no ΔI_C, and evoked a larger ΔI_Cl. Brighter light steps resulted in longer periods of spike decrease and larger ΔI_Cl, and, at -5, light started to elicit ΔI_C. As the light step became even brighter, the decrease of spike activity lasted longer, and ΔI_C and ΔI_Cl became larger and longer. We measured the light sensitivity of ΔI_C and ΔI_Cl to 500 nm light in all 20 sOFFαGCs, and the average ± SD response–intensity (ΔI_C–Log I and ΔI_Cl–Log I) relationships are plotted and fitted with the Hill equation in Figure 4H. The average threshold for ΔI_C was near -6.1 (0.55 Rh^*rod^-1sec^-1) with a dynamic range of 3.0 log units, and the average threshold for ΔI_Cl was near -8.5 (0.0022 Rh^*rod^-1sec^-1) with a dynamic range of 5.9 log units. The average threshold of the spike decrease was -8.0 (0.007 Rh^*rod^-1sec^-1). These results suggest that ΔI_C of sOFFαGCs is probably mediated by HBC_MCs, similar to the bipolar cells that mediate ΔI_C in tOFFαGCs. ΔI_Cl of sOFFαGCs is likely to be mediated by the AII amacrine cells who have very high sensitivity to 500 nm lights (Table 1). Because the dynamic range of ΔI_Cl is much wider than that of the AII ACs, another AC with mixed rod and cone inputs (possibly AC_M2) may also be involved in mediating ΔI_Cl in sOFFαGCs. Because the threshold of spike response was closer to ΔI_Cl than to ΔI_C, ΔI_Cl should contribute significantly more to the spike responses. This may be partially explained by our observation that the average dark membrane potential of sOFFαGCs was near -51 mV, ∼10 mV more depolarized than E_Cl. This is in contrast to the ONαGCs and tOFFαGCs whose average dark membrane potentials are much closer to E_Cl, and thus, in these cells, ΔI_Cl could only contribute to the light response by voltage shunting. The difference in dark membrane potential may also explain why sOFFαGCs exhibit spontaneous spikes in darkness whereas ONαGCs and tOFFαGCs do not.

Average response thresholds and dynamic range as well as the dark membrane potentials of ON ΔI_C and ΔI_Cl of the sOFFαGCs are listed in Table 1 (bottom).

Mouse α ganglion cells exhibit three distinct types of light responses: ON, transient OFF, and sustained OFF

By using loose-patch, whole-cell voltage-clamp and Lucifer yellow fluorescent techniques, we studied the light responses of 51 ganglion cells with α-cell-like morphology in dark-adapted mouse retina and found that they can be clearly divided into three types. The first type, the ONαGCs, exhibits no spike activity in darkness, increased spikes in light, sustained light-evoked inward cation current (ΔI_C) at E_Cl, sustained light-evoked chloride current (ΔI_Cl) of varying amplitude at E_C, and large soma (20–25 μm in diameter) with α-cell-like dendritic field ∼180–350 μm stratifying near 70% of the IPL depth. The second type, the tOFFαGCs, exhibit no spike activity in darkness, transient increased spikes at light offset, small sustained light-evoked outward ΔI_C in light and large transient inward ΔI_C at light offset, and a sustained outward ΔI_Cl in light. Morphologically, the tOFFαGCs are similar to the ONαGCs except for that their dendrites stratified near 30% of the IPL depth. The third type, the sOFFαGCs, exhibit maintained spike activity of 5–10 Hz in darkness, sustained decrease spikes in light, sustained outward ΔI_C, sustained outward ΔI_Cl in light, and a morphology similar to the tOFFαGCs.

Our data agree with the ON and OFF sublaminar rule of the retinal IPL very well: ganglion cells with dendrites ramified in sublamina A display OFF responses and those with dendrites in sublaminar B display ON responses (Nelson et al., 1978). On the other hand, α ganglion cells in mammalian retinas are believed to have transient light responses (Cleland et al., 1975; Peichl and Wassle, 1981; Saito, 1983); however, in the mouse retina, we found that only one-quarter of the α ganglion cells are transient (tOFFαGCs). This difference may result from species difference or different adaptational conditions (all of our recordings were performed under infrared illumination). Alternatively, because the transient light responses described in previous studies are correlated with ganglion cells of large somas without detailed dendritic morphology, they may represent other populations of ganglion cells with large somas.

Synaptic circuitries of αGCs: each type of αGCs receive light-evoked signals from BCs and ACs with different rod/cone inputs

In this study, we used the whole-cell voltage clamp technique to separate the light-evoked BC and AC inputs (ΔI_C and ΔI_Cl, respectively) to αGCs. By comparing the response threshold and dynamic ranges of ΔI_C and ΔI_Cl and spike activities of each type of αGCs with the corresponding parameters of preganglion cells, we proposed a functional synaptic circuitry of the BC and AC inputs to αGCs (Fig. 5). It is worth noting that this circuitry diagram includes a minimum number of circuit components, although our data may also be explained by more complex schemes. The outlines of our proposed circuitry are consistent with the general plan set forth by anatomical analysis but with several new and more detailed findings revealing how synapses in the inner retina function.

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Figure 5.

Synaptic circuit diagram of the ONαGCs, tOFFαGCs, and sOFFαGCs in the mouse retina. R, Rods; C(M/s), M-pigment-dominated cones; C(S/m), S-pigment-dominated cones; DBC_R, rod depolarizing bipolar cell; DBC_MC, M-cone-dominated depolarizing bipolar cell; HBC_MC, M-cone-dominated hyperpolarizing bipolar cell; HBC_SC, S-cone-dominated bipolar cells; AII, AII amacrine cells; AC_M1, amacrine cell with mixed rod–cone inputs in the ON αGC pathway; AC_M2, amacrine cell with mixed rod–cone inputs in the OFFαGC pathway; arrows, chemical synapses (red, glutamatergic; blue, GABAergic/glycinergic; + sign, preserving; and - sign, inverting); (red), electrical synapses; PRL, photoreceptor layer; OPL, outer plexiform layer; INL, inner nuclear layer; IPL, inner plexiform layer (a, sublamina a; b, sublamina b); GCL, ganglion cell layer.

We found that the light responses of ONαGCs are quite homogenous, and they all appear to receive excitatory inputs from DBC_MCs, which give a mixed rod/M-cone signal with a rod-like threshold and a wide (combined rod–cone) dynamic range. The rod signals are mediated by either the rod–DBC_R–AII–DBC_C (ON1) pathway or the rod–cone–DBC_C (ON2) pathway (Bloomfield and Dacheux, 2001; Demb and Pugh, 2002), and the cone signals are mediated directly by the M-cone–DBC_MC synapse. In all 28 ONαGCs, we never observed a response threshold higher then 20 Rh^*rod^-1sec^-1 or an operating range beyond 1000 Rh^*rod^-1sec^-1, suggesting that the contribution of the S-cone inputs is minor. The only significant variation among ONαGCs is their spike response frequency and the amplitude (not the threshold or dynamic range) of ΔI_Cl. Because the dark membrane potential of these ganglion cells is close to E_Cl, we suggest that the primary function of the amacrine cell (AC_M1) input is to shunt the DBC_MC-mediated input. The inverse relationship between ΔI_Cl amplitude and the frequency of light-evoked spikes in the ONαGCs supports this notion.

Our finding that all ONαGCs exhibit homogenous response–intensity function (Fig. 1H) contrasts a recent study that reports four groups of ON ganglion cells in the mouse retina, each having a distinct response–intensity curve (Deans et al., 2002). Because responses of these ganglion cells were recorded with extracellular electrodes and the cell morphology was not revealed, the four groups may reflect both α and non-α ON ganglion cells (and perhaps spiking displaced amacrine cells). On the basis of the response threshold and dynamic range, it appears that ONαGCs belong to the groups with intermediate sensitivity and wide operating range (mixed rod–cone inputs) and not those of high (rod driven) or low sensitivity (cone driven).

The two types of OFFαGCs display drastically different responses, and thus their BC and AC inputs are different. tOFFαGCs exhibit transient increase of spikes at light offset with a very high threshold, and the sOFFαGCs exhibit spike decrease when the light is turned on with an extremely low threshold. These cells seem to receive two excitatory bipolar cell inputs: one is mediated by a sustained HBC with an M-cone-dominated signal and the other by a transient HBC (with an off overshoot response) with an S-cone-dominated signal (J.-J. Pang and S. M. Wu, unpublished data) and an AC input with mixed rod/M-cone inputs (AC_M2). The HBC_SC-mediated transient OFF ΔI_C is responsible for the transient OFF spike response. The HBC_MC-mediated ON ΔI_C and AC-mediated ΔI_Cl are both inhibitory (because they are outward currents), and, because tOFFαGCs do not exhibit spontaneous spikes in darkness, these outward currents do not serve much physiological function (silent synapses). On the other hand, sOFFαGC responses are extremely sensitive to 500 nm light, with a threshold lower than HBC_MCs and even lower than HBC_Rs (Field and Rieke, 2002). It appears that sOFFαGC responses are mediated primarily by the AII AC-mediated ΔI_Cl, which has a threshold of near 0.001 Rh^*rod^-1sec^-1 (Pang and Wu, unpublished data) at the low light intensity range. An HBC_MC-mediated ΔI_C is also involved in mediating the spike responses of the cells at higher light intensities. These results also suggest that the feedforward synapse from AII AC to sOFFαGCs are stronger (or of higher gain) than the feedback synapse from AII AC to HBC_MCs and the electrical synapse between AII AC and DBC_MCs (Fig. 5), because the AII response to dim light (below 0.01 Rh^*rod^-1sec^-1) could only be observed in ΔI_Cl of the sOFFαGCs.

A major difference between sOFFαGCs and the other two types of αGCs is that sOFFαGCs exhibit spontaneous spike activity of 5–10 Hz in darkness, whereas the other αGCs do not. This can be partially explained by our finding that sOFFαGCs have an average dark membrane potential (-51 ± 7 mV) ∼10 mV more positive than the other two types of αGCs (-63 ± 6 and -61 ± 7 mV for the ONαGCs and tOFFαGCs, respectively). Another factor that may contribute to the spontaneous spiking in sOFFαGCs is that it has been shown, at least in the salamander retina, that the sustained OFF bipolar cells exhibit large sEPSCs in darkness (Wu et al., 2000). These sEPSCs in HBCs may trigger sEPSCs in sOFFαGCs. As sOFFαGCs are maintained at a relatively more depolarized voltage in darkness, large sEPSCs may depolarize the cell above the threshold of action potentials and thus cause spontaneous spike activities.

In our voltage-clamp experiments, we found an abrupt voltage-dependent increase of sIPSCs that occurred between -60 and -40 mV in all OFFαGCs (both tOFFαGCs and sOFFαGCs) but not in ONαGCs. One possible explanation for this abrupt voltage-dependent increase of sIPSCs is that the depolarizing current needed to maintain the positive holding potential may leak into amacrine cells through gap junctions (Xin and Bloomfield, 1997), which would facilitate the release of GABAergic or glycinergic vesicles from amacrine cells to the recorded ganglion cell (Tian et al., 1998). Anatomical studies have shown that reciprocal electrical synapses exist between OFFαGCs and GABAergic ACs in mammalian retinas (Dacey and Brace, 1992; Jacoby et al., 1996; Bloomfield and Xin, 1997). Our voltage-clamp results suggest that membrane depolarization in OFFαGCs, such as occurs during action potentials, may cause considerable depolarizing current flow into ACs (AC_M2) through the gap junctions. Because AC neurotransmitters are inhibitory, this reciprocal electrical synapse may serve as a negative feedback circuit for spiking activities in the OFFαGCs (Fig. 5).

In summary, the synaptic circuitry diagram (Fig. 5) derived from our study is primarily consistent with the general plan for ON and OFF ganglion cells set forth by anatomical studies, and thus our results provide the first physiological support for the organization found in the mouse retina. Additionally, our data elucidate which synapses serve physiological function and which ones do not, as well as which synapses are more dominant than others in mediating the light responses of the cells. For example, our data suggest that the primary function of the AC inputs to ONαGCs is to regulate the spiking frequency of the cells by voltage shunting and that the AII AC feedforward synapse is the dominant inputs for sOFFαGCs, at least within the low light intensity range. In addition, the outward ON ΔI_C and ON ΔI_Cl from HBC_MC and ACs to tOFFαGCs serve little physiological function, and the transient inward OFF ΔI_C from HBC_SCs is the dominant input for the tOFFαGCs spike response. Finally, OFFαGCs, rather than ONαGCs, are likely to make functional reciprocal electrical synapses with ACs. These physiological characteristics of αGCs could not be revealed by the previous anatomical studies, and thus they provide new insights on our understanding of the functional circuitry of the mammalian retina.