Abstract
Sensory coding relies on ensembles of co-active neurons, but these ensembles change from trial to trial of the same stimulus. This is due in part to wide variability in the responsiveness of neurons within these ensembles, with some neurons responding regularly to a stimulus while others respond inconsistently. The specific functional properties that cause neurons to respond more or less consistently have not been thoroughly explored. Here, we have examined neuronal ensembles in the zebrafish tectum responsive to repeated presentations of a visual stimulus, and have explored how these populations change when the orientation or brightness of the stimulus is altered. We found a continuum of response probabilities across the neurons in the visual ensembles, with the most responsive neurons focused toward the spatial centre of the ensemble. As the visual stimulus was made dimmer, these neurons remained active, suggesting higher overall responsiveness. However, these cells appeared to represent the most consistent end of a continuum, rather than a functionally distinct “core” of highly responsive neurons. Reliably responsive cells were broadly tuned to a range of stimulus orientations suggesting that, at least for this stimulus property, tight stimulus tuning was not responsible for their consistent responses.
Highlights
Sensory coding relies on ensembles of co-active neurons, but these ensembles change from trial to trial of the same stimulus
Given the generally high intrinsic noise and broad tuning preferences of individual neurons, the information that can be encoded by single neurons is insufficient for the fine discrimination of stimuli that animals achieve[1,2,3,4,5]
The idea that cells form assemblies to encode information as a population was proposed more than 50 years ago[6], suggesting that integration of synchronous activity from populations of neurons underlies the enormous breadth observed in encoding capacity[7,8,9,10]
Summary
Sensory coding relies on ensembles of co-active neurons, but these ensembles change from trial to trial of the same stimulus. With the goal of defining these properties of neural ensembles, we have observed large populations of individually-resolvable neurons in the zebrafish tectum through numerous trials of a consistent visual stimulus First and foremost, this was intended to reveal the range of response probabilities present among the neurons in the observed ensembles. We have looked at the changes in ensemble composition over a range of stimulus intensities and orientations These experiments aim to reveal the relative contributions made by baseline responsiveness, stimulus specificity, and tuning breadth, to the probability of each neuron’s firing in a given trial, and to the functional composition of visually-responsive ensembles in the zebrafish tectum
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