Spike Timing and Information Transmission at Retinogeniculate Synapses

Relayed retinal spikes have a stronger correlation with a visual stimulus than nonrelayed spikes. A, Three receptive field response maps made using three categories of spikes from a representative retinal ganglion cell: “all” spikes, “relayed” spikes, and “nonrelayed” spikes. Response maps were made using an equal number of spikes, and the maps are shown with the same color scale (pixel brightness) to compare response amplitude (correlation between stimulus and response) across the three categories of spikes. The histograms shown below the receptive field maps show the distribution of preceding ISIs for each category of spikes. The distribution of ISIs for relayed spikes is shifted to the left of that for nonrelayed spikes, indicating that relayed spikes are more likely to occur after short ISIs. B, Difference index histogram showing the relationship between the amplitudes of center subregions calculated from relayed and nonrelayed spikes across cell pairs (n = 17 pairs). The difference index is calculated as the difference between these amplitude values for relayed and nonrelayed spikes divided by their sum. Positive values indicate greater center amplitude for relayed spikes, and negative values indicate greater center amplitude for nonrelayed spikes.

Visual stimuli that best match the receptive fields of the retinal ganglion cell and LGN neuron are more likely to evoke relayed spikes and are more likely to drive short ISI responses. A, Scatterplot showing the relationship between the visual stimulus preceding relayed and nonrelayed retinal spikes and the STRF map of the retinal ganglion cell—quantified with the NDP—as a function of the strength of connection, “contribution,” between the retina and LGN. Contribution is equal to the percentage of LGN spikes that were evoked from the recorded retinal ganglion cell. Data points in vertical register (relayed and nonrelayed) are from the same pair of cells. Mean NDP values: Relayed spikes, 0.21 ± 0.2; nonrelayed spikes, 0.15 ± 0.2. B, Scatterplot showing the relationship between the visual stimulus preceding relayed and nonrelayed spikes and the STRF map of the LGN neuron—quantified with the NDP—as a function of the strength of connection, “contribution,” between the retina and LGN. Mean NDP values: relayed spikes = 0.19 ± 0.2, nonrelayed spikes = 0.08 ± 0.2. C, Scatterplot showing the relationship—quantified with the NDP—between the visual stimulus and the STRF map of a cell for relayed and nonrelayed retinal spikes. The open symbols indicate values when using the STRF of the retinal ganglion cell, and the filled symbols indicate values when using the STRF of the LGN cell. When using either the retinal or LGN STRF, NDP values are significantly greater for relayed spikes compared with nonrelayed spikes. D, Mean ISI distribution from our sample of retinal ganglion cells. This distribution was calculated by averaging the normalized histograms for each retinal cell. Error bars indicate SEM. E, Relationship between the efficacy of first and second retinal spikes in a pair as a function of ISI. Efficacy is the percentage of retinal spikes that drive LGN spikes. Second spikes have a greater efficacy than first spikes for ISIs up to ∼30 ms. The gray bands denote SEM. F, Histogram showing the mean relationship between normalized dot product values and retinal spikes that follow different ISIs, where the normalized dot product is a measure of how well the white-noise stimulus that preceded each spike matched the spatiotemporal receptive field map of each cell (see Materials and Methods). Retinal spikes that follow short ISIs are more likely to be evoked by stimuli that best match the receptive field of the retinal ganglion cell. Error bars indicate SEM.

Scatterplot showing an increased latency between stimulus and response for relayed retinal spikes compared with nonrelayed spikes. Latency is taken from the impulse response of each spike class and corresponds to the time between stimulus and maximum response. Across our sample of cell pairs, relayed spikes have a significantly longer latency than nonrelayed spikes. The crosshairs indicate mean and SEM.

Analysis of spike train statistics demonstrates that retinal firing events have high precision. A, Raster plot showing the occurrence of retinal spikes during 100 repetitions of a white-noise stimulus (300 ms of the 10 s stimulus shown). Relayed spikes are indicated with red ticks, and nonrelayed spikes are indicated with black ticks. B, D, F, Peristimulus time histograms for each spike class—all spikes, relayed spikes, and nonrelayed spikes—binned at 0.3 ms and smoothed. The solid lines indicate firing probability for each time bin. The vertical gray shading indicates the sum of all Gaussians fit to each event. Note that events distributed over a single bin could not be fitted by a Gaussian and are excluded from analysis. C, E, G, Scatterplots showing spike count variance versus spike count for the three categories of spikes: all spikes, relayed spikes, and nonrelayed spikes. Events were identified separately for each category of spikes. The diagonal lines indicate firing statistics expected by a purely Poisson spike generator; the lower scalloped lines denote the lowest possible variance at each mean spike count. Frequency/occurrence distributions are shown to the right of each scatterplot with a dashed line indicating the mean variance. The figure inset shows an expanded view of C illustrating the extent to which scallops are nested.