Abstract
Persistent reduction in sensory drive in early development results in multiple plastic changes of different cortical synapses. How these experience-dependent modifications affect the spatio-temporal dynamics of signal propagation in neocortical circuits is poorly understood. Here we demonstrate that brief visual deprivation significantly affects the propagation of electrical signals in the primary visual cortex. The spatio-temporal spread of circuit activation upon direct stimulation of its input layer (Layer 4) is reduced, as is the activation of L2/3 – the main recipient of the output from L4. Our data suggest that the decrease in spatio-temporal activation of L2/3 depends on reduced L4 output, and is not intrinsically generated within L2/3. The data shown here suggest that changes in the synaptic components of the visual cortical circuit result not only in alteration of local integration of excitatory and inhibitory inputs, but also in a significant decrease in overall circuit activation. Furthermore, our data indicate a differential effect of visual deprivation on L4 and L2/3, suggesting that while feedforward activation of L2/3 is reduced, its activation by long range, within layer inputs is unaltered. Thus, brief visual deprivation induces experience-dependent circuit re-organization by modulating not only circuit excitability, but also the spatio-temporal patterns of cortical activation within and between layers.
Highlights
Sensory experience sculpts the connectivity and function of neocortical circuits (Katz and Shatz, 1996; Finnerty et al, 1999; Cheetham et al, 2007; Feldman, 2009)
Intensity/response curves were constructed to verify that the amplitude of Local field potentials (LFP) and the voltage sensitive dye (VSD) signals followed the intensity of the stimulus with a similar trend
The hypothesis that the observed modifications in circuit activation depend on plastic changes induced by MD was examined further with a series of experiments
Summary
Sensory experience sculpts the connectivity and function of neocortical circuits (Katz and Shatz, 1996; Finnerty et al, 1999; Cheetham et al, 2007; Feldman, 2009). Lack of environmental stimuli during sensitive windows for circuit development impairs sensory function permanently (Hubel and Wiesel, 1970; Goodman and Shatz, 1993). Experimental approaches that isolate the circuit into its synaptic components have been extremely successful in identifying plastic modifications at different sites of the visual cortical network (Fagiolini et al, 2004; Maffei et al, 2006; Katagiri et al, 2007; Maffei and Fontanini, 2009). Due to limited access to the deeper layers, these studies concentrated on the analysis of the circuits in L1 and L2/3
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