Local and Global Effects ofIhDistribution in Dendrites of Mammalian Neurons

Abstract

The hyperpolarization-activated cation currentI_hexhibits a steep gradient of channel density in dendrites of pyramidal neurons, which is associated with location independence of temporal summation of EPSPs at the soma. In striking contrast, here we show by using dendritic patch-clamp recordings that in cerebellar Purkinje cells, the principal neurons of the cerebellar cortex,I_hexhibits a uniform dendritic density, while location independence of EPSP summation is observed. Using compartmental modeling in realistic and simplified dendritic geometries, we demonstrate that the dendritic distribution ofI_honly weakly affects the degree of temporal summation at the soma, while having an impact at the dendritic input location. We further analyze the effect ofI_hon temporal summation using cable theory and derive bounds for temporal summation for any spatial distribution ofI_h. We show that the total number ofI_hchannels, not their distribution, governs the degree of temporal summation of EPSPs. Our findings explain the effect ofI_hon EPSP shape and temporal summation, and suggest that neurons are provided with two independent degrees of freedom for different functions: the total amount ofI_h(controlling the degree of temporal summation of dendritic inputs at the soma) and the dendritic spatial distribution ofI_h(regulating local dendritic processing).