Abstract
Excitatory and inhibitory cortical layer IV neurons have distinctive response properties. Thalamocortical connectivity that may underlie differences was examined using cross-correlation analyses of pairs of thalamic and cortical neurons in the rat whisker/barrel system. Cortical layer IV cells discharging fast spikes, presumed inhibitory neurons, were distinguished from regular-spike units, presumed excitatory neurons, by the extracellular waveform shape. Regular-spike neurons fired less robustly and had smaller receptive fields (RFs) and greater directional tuning than fast-spike cells. Presumed excitatory neurons were less likely to receive thalamocortical connections, and their connections were, on average, weaker. RF properties of thalamic inputs to both cell types were equivalent, except that the most highly responsive thalamic cells contacted only fast-spike neurons. In contrast, the size and directional tuning of cortical RFs were related to the number of detectable thalamocortical inputs. Connected thalamocortical pairs were likely to have matching RF characteristics. The smaller, more directionally selective RFs of excitatory neurons may be a consequence of their weaker net thalamic drive, their more nonlinear firing characteristics and pervasive feedforward inhibition provided by strongly driven, broadly tuned inhibitory neurons.
Highlights
Excitatory and inhibitory cortical layer IV neurons have distinctive response properties
In whisker-related cortical barrels, inhibitory cells are driven by deflections of the “principal” whisker (PW) of the barrel and several adjacent whiskers (AWs), yet many excitatory cells respond to the PW alone; receptive fields (RFs) of thalamocortical neurons vary in size
Waveform-based classification of cortical cells Cortical units were classified as Fast-spike units (FSUs) or Regular-spike units (RSUs) by the time course of a random sample of action potentials recorded for each unit
Summary
Excitatory and inhibitory cortical layer IV neurons have distinctive response properties. The smaller, more directionally selective RFs of excitatory neurons may be a consequence of their weaker net thalamic drive, their more nonlinear firing characteristics and pervasive feedforward inhibition provided by strongly driven, broadly tuned inhibitory neurons. An explicit assumption is that inhibitory and excitatory cells receive inputs from the same pool of thalamocortical neurons but process them differently. In addition to their larger RFs, inhibitory neurons have higher spontaneous and evoked firing rates and less directional selectivity (Simons and Carvell, 1989; Armstrong-James et al, 1993; Kyriazi et al, 1994). Slower action potentials, called “regular spikes,” are discharged by excitatory, spiny cells, which compose ϳ90% of the cortical population (Beaulieu, 1993); regular spikes are discharged by a sparse subpopulation of GABAergic neurons (Kawaguchi and Kubota, 1993; Gibson et al, 1999)
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