Activity-Dependent Matching of Excitatory and Inhibitory Inputs during Refinement of Visual Receptive Fields  Huizhong W. Tao, Mu-ming Poo  Neuron  Volume.

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Activity-Dependent Matching of Excitatory and Inhibitory Inputs during Refinement of Visual Receptive Fields  Huizhong W. Tao, Mu-ming Poo  Neuron  Volume 45, Issue 6, Pages 829-836 (March 2005) DOI: 10.1016/j.neuron.2005.01.046 Copyright © 2005 Elsevier Inc. Terms and Conditions

Figure 1 Mapping the Visual Receptive Field of Developing Xenopus Tectal Neurons (A) Example traces of synaptic responses in a tectal cell, each evoked by a square unit light stimulus (duration 1.5 s, thick line) and recorded at Vh = −45 and 0 mV, the reversal potential of inhibitory (Ei) and excitatory (Ee) synaptic currents for this particular cell, respectively. Dashed vertical lines delineate the window for measuring the integrated charge associated with the compound synaptic currents (CSCs). Scale: 30 (upper)/40 pA, 250 ms. (B) Bicuculline reversibly blocked light stimulus-evoked outward currents recorded in the tectal cell (Vh = 0 mV). The stimulus was a 150 ms dimming stimulus (top trace). The synaptic response traces are average of five events before (top) and 5 min after (middle) local application of bicuculline (10 μM) to the tectum and after washout of bicuculline (bottom). Scale, 25 pA, 250 ms. (C) Average of ten glutamatergic (red) and ten GABAergic (blue) CSCs repeatedly evoked by the same unit stimulus (with the polarity of excitatory CSCs inverted). Note the delay of onset for the two types of CSCs. Unit scale: 2(red)/5(blue) pA. (D) (Top) Traces of Off visual responses, average of two repeats and displayed in accordance with the relative position of the corresponding unit stimulus, are shown for a tectal cell in a stage 48 tadpole. exc, glutamatergic CSCs (Vh = Ei); inh, GABAergic CSCs (Vh = Ee). (Bottom) Reconstructed eRF and iRF, displayed with a linear color scale. Color of each element in the grid represents the measured total charge (pC) of the corresponding CSCs shown above. (E) Similar display of RFs of a cell from a stage 44 tadpole from the same batch as that shown in (D). Neuron 2005 45, 829-836DOI: (10.1016/j.neuron.2005.01.046) Copyright © 2005 Elsevier Inc. Terms and Conditions

Figure 2 Developmental Changes in the Topography of Excitatory and Inhibitory Inputs to the Tectal Neuron (A) (Top) Example eRF and iRF pairs for four tectal cells from stage 43-44 tadpoles. (Bottom) Correlation between the strength of excitatory and inhibitory inputs activated by the same unit stimulus. Each data point represents the magnitude of CSCs charge for excitatory input (normalized to the largest unit response of the same cell) and the corresponding inhibitory input. Data points were from eight cells including those shown above. Correlation coefficient = 0.10, calculated from those data points shown in the graph and displayed by the red line. (B and C) Similar mapping and correlation analysis for stage 46 (B) and 48 (C) tadpoles. Correlation coefficient = 0.43 (B) and 0.74 (C). (D) Average RF size at different stages of development. RF area is defined as the percentage of the visual area that covers all unit stimuli that consistently elicited responses. Bar = SEM (n = 24–31 cells from seven to eight tadpoles in each group). (E) Blank, the average distance between the centers of eRF and iRF of the same cell. Gray, the average correlation coefficient, which was calculated for excitatory and inhibitory responses from each cell. Same group of cells as in (D). (F) Developmental changes in the average total integrated synaptic conductance (ISC). The total ISC for inhibitory inputs at stage 47 and 48 is significantly smaller than at stage 43-44 (p < 0.01, t test). (G) Developmental changes in the average ISC. The value for inhibitory inputs at stage 47 and 48 is significantly smaller than at stage 43-44, the value for excitatory inputs at stage 48 is significantly larger than at stage 43-44 (p < 0.01). (H) Example recording of unitary EPSCs using minimal stimulation of RGC axons. Stimulation voltage applied to the loose patch electrode placed on the retina was increased from 4 to 12 V in 2 V steps. Unitary EPSCs were first obtained at 8 V. (Top) Superimposed traces of EPSCs (or failures) evoked by 8 V stimulation. Scale, 20 pA, 5 ms. (I) Average amplitude of unitary EPSCs recorded from tectal cells (Vh = −70 mV) in stage 44 and stage 47-48 tadpoles. The value for each cell was determined from eight to ten measurements of EPSCs at a stimulation level 1.2- to 1.5-fold of the threshold level for evoking EPSCs. (J) (Top) Example traces of spontaneous IPSCs (Vh = 0 mV, under constant background light, see Experimental Procedures) from tectal cells in a stage 44 (upper) and stage 48 (lower) tadpole, respectively. Sample unitary sIPSCs at a higher time resolution are shown on the right. Scale, 25 pA, 1 s or 70 ms. (Bottom) Average cumulative distribution of unitary sIPSC amplitudes (identified as isolated single IPSCs) from 5–10 min continuous recordings and at least 300 sIPSC events per cell from stage 44 or 47-48 tadpoles. Neuron 2005 45, 829-836DOI: (10.1016/j.neuron.2005.01.046) Copyright © 2005 Elsevier Inc. Terms and Conditions

Figure 3 Effects of Blocking or Elevating GABAA Receptor Activity on the Refinement of eRF and iRF (A and B) Sample RFs of four cells from stage 48 tadpoles that have been injected with bicuculline (A) or diazepam (B) daily, beginning from stage 40. (C and D) The average RF area for tadpoles injected daily with bicuculline (“bic”), diazepam (“diaz”), and the vehicle solution (“veh”). Bar = SEM. *Significant changes as compared to the controls (p < 0.01, t test). N = 20–29 cells from six to seven tadpoles in each group. (E and F) The effects of drug treatments on the topography of RFs, displayed as in (C). (G and H) Changes in the total ISCs (G) or average ISCs (H) after the drug treatments. (Left) Excitatory inputs. (Right) Inhibitory inputs. *p < 0.05, t test. Kolmogorov-Smirnov test shows normal distribution of data. Neuron 2005 45, 829-836DOI: (10.1016/j.neuron.2005.01.046) Copyright © 2005 Elsevier Inc. Terms and Conditions

Figure 4 Effects of Manipulating GABAergic Transmission on the Spiking Activity of Tectal Cells (A) Spikes evoked by a dimming stimulus (duration 150 ms, onset marked by the arrow head), as recorded by a loose-patch electrode at the tectal cell soma, before and 10 min after local perfusion of bicuculline (10 μM) on the tectum (stage 41). (B1) Traces of continuous recording of spontaneous spikes under constant ambient light before and 15 min after bicuculline application (stage 42). (B2 and B3) Distribution of interspike intervals (ISIs) before (B2) and after (B3) bicuculline application, for the same cell shown in (B1). Data were from 8 min recording in each condition. Number of counts in each bin is normalized to the total number of spikes during control recording session before drug application. (C) Dimming stimulus-induced spiking before and 15 min after the perfusion with diazepam (10 μM) in a stage 44 tadpole. (D) The effect of diazepam on the spontaneous spiking (stage 42), displayed as in (B). (E) Summary of the acute effect of drug treatments. Tadpoles of stage 41-47 were examined. Effects of treatment with each drug were similar at different stages examined and data were pooled. (Left) The average total number of spikes evoked by the dimming stimulus, normalized to that before the drug (or vehicle) application (n = 7 cells for each group, 20 to 30 measurements in each condition). “Veh” is 0.1% propylene glycol in the external solution. (Middle) Normalized average firing rate of spontaneous spikes (bic, n = 10; diaz, n = 10; veh, n = 6) after the drug application. (Right) Percentage of high-frequency discharge of spontaneous spiking (ISI < 100 ms) in the total number of spikes after the drug application, normalized to that during control period. There is a 2-fold increase after bicuculline application. *p < 0.05, paired t test. Neuron 2005 45, 829-836DOI: (10.1016/j.neuron.2005.01.046) Copyright © 2005 Elsevier Inc. Terms and Conditions