Factors mediating powerful voltage attenuation along CA1 pyramidal neuron dendrites

We performed simultaneous patch-electrode recordings from the soma and apical dendrite of CA1 pyramidal neurons in hippocampal slices, in order to determine the degree of voltage attenuation along CA1 dendrites. Fifty per cent attenuation of steady-state somatic voltage changes occurred at a distanc...

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Bibliographic Details
Published in:The Journal of physiology 2005-10, Vol.568 (1), p.69-82
Main Authors: Golding, Nace L., Mickus, Timothy J., Katz, Yael, Kath, William L., Spruston, Nelson
Format: Article
Language:English
Subjects:
Animals
Cell Physiology
Dendrites - physiology
Excitatory Postsynaptic Potentials - physiology
Hippocampus - physiology
Hippocampus - ultrastructure
In Vitro Techniques
Male
Models, Neurological
Neural Conduction - physiology
Patch-Clamp Techniques
Pyramidal Cells - physiology
Pyramidal Cells - ultrastructure
Rats
Rats, Wistar
Synaptic Transmission
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Summary:We performed simultaneous patch-electrode recordings from the soma and apical dendrite of CA1 pyramidal neurons in hippocampal slices, in order to determine the degree of voltage attenuation along CA1 dendrites. Fifty per cent attenuation of steady-state somatic voltage changes occurred at a distance of 238 μm from the soma in control and 409 μm after blocking the hyperpolarization-activated (H) conductance. The morphology of three neurons was reconstructed and used to generate computer models, which were adjusted to fit the somatic and dendritic voltage responses. These models identify several factors contributing to the voltage attenuation along CA1 dendrites, including high axial cytoplasmic resistivity, low membrane resistivity, and large H conductance. In most cells the resting membrane conductances, including the H conductances, were larger in the dendrites than the soma. Simulations suggest that synaptic potentials attenuate enormously as they propagate from the dendrite to the soma, with greater than 100-fold attenuation for synapses on many small, distal dendrites. A prediction of this powerful EPSP attenuation is that distal synaptic inputs are likely only to be effective in the presence of conductance scaling, dendritic excitability, or both.
ISSN:0022-3751
1469-7793
DOI:10.1113/jphysiol.2005.086793