Abstract
Hearing, vision, touch: underlying all of these senses is stimulus selectivity, a robust information processing operation in which cortical neurons respond more to some stimuli than to others. Previous models assume that these neurons receive the highest weighted input from an ensemble encoding the preferred stimulus, but dendrites enable other possibilities. Nonlinear dendritic processing can produce stimulus selectivity based on the spatial distribution of synapses, even if the total preferred stimulus weight does not exceed that of nonpreferred stimuli. Using a multi-subunit nonlinear model, we demonstrate that stimulus selectivity can arise from the spatial distribution of synapses. We propose this as a general mechanism for information processing by neurons possessing dendritic trees. Moreover, we show that this implementation of stimulus selectivity increases the neuron's robustness to synaptic and dendritic failure. Importantly, our model can maintain stimulus selectivity for a larger range of loss of synapses or dendrites than an equivalent linear model. We then use a layer 2/3 biophysical neuron model to show that our implementation is consistent with two recent experimental observations: (1) one can observe a mixture of selectivities in dendrites that can differ from the somatic selectivity, and (2) hyperpolarization can broaden somatic tuning without affecting dendritic tuning. Our model predicts that an initially nonselective neuron can become selective when depolarized. In addition to motivating new experiments, the model's increased robustness to synapses and dendrites loss provides a starting point for fault-resistant neuromorphic chip development.
Highlights
The standard model of neuronal integration in neuroscience, which owes much to Hubel and Wiesel (Hubel and Wiesel, 1959), produces stimulus selectivity at the neuronal level by linearly integrating inputs within a single compartment
Why hyperpolarization does not broaden dendritic tuning like it does for somatic tuning? Taken together these two sets of observations call for a new model and we propose here that these observations can be accounted for by the properties of dendrites
Dendrites enable stimulus selectivity based on the spatial distribution of synapses We show here how it is possible for a neuron to implement stimulus selectivity even if both the preferred and the non-preferred inputs make the same number of equal weight synaptic contacts
Summary
The standard model of neuronal integration in neuroscience, which owes much to Hubel and Wiesel (Hubel and Wiesel, 1959), produces stimulus selectivity at the neuronal level by linearly integrating inputs within a single compartment. This model neglects the rich and in many cases spatially precise structure of the dendritic tree associated with many neuronal cell types throughout the brain (Stuart et al, 2016). Several groups have recently presented data which is counter-intuitive given this standard model, as applied to orientation selectivity in the visual cortex. Why hyperpolarization does not broaden dendritic tuning like it does for somatic tuning? Taken together these two sets of observations call for a new model and we propose here that these observations can be accounted for by the properties of dendrites
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