Comparison of the Morphological and Electrotonic Properties of Renshaw Cells, Ia Inhibitory Interneurons, and Motoneurons in the Cat

doi:10.1152/jn.00533.2003

Comparison of the Morphological and Electrotonic Properties of Renshaw Cells, Ia Inhibitory Interneurons, and Motoneurons in the Cat

T. V. Bui¹, S. Cushing¹, D. Dewey², R. E. Fyffe² and P. K. Rose¹

¹ Canadian Institutes of Health Research Group in Sensory-Motor Systems, Department of Physiology, Queen's University, Kingston K7L 3N6, Canada; ² Department of Anatomy, Wright State University, Dayton, Ohio 45435

Submitted 2 June 2003; accepted in final form 20 July 2003

The morphological and electrotonic properties of 4 motoneurons,8 Ia inhibitory interneurons, and 4 Renshaw cells were compared.The morphological analysis, based on 3-D reconstructions ofthe cells, revealed that dendrites of motoneurons are longerand more extensively branched. Renshaw cells have dendritesthat are shorter and simpler in structure. Dendrites of Ia inhibitoryinterneurons could be as long as those of motoneurons but thebranching structure resembled that of Renshaw cells. Compartmentalmodels were used to determine the electrotonic properties ofthe paths from each dendritic terminal to the soma. The attenuationsof steady-state voltage changes in motoneurons were 3 and 7times larger than in Ia inhibitory interneurons and Renshawcells, respectively. The same relative order was observed forcurrent attenuation and electrotonic length. The dendritic inputresistances in Renshaw cells were 2 and 4 times larger thanin Ia inhibitory interneurons and motoneurons, respectively.The difference in these electrotonic properties increased duringhigher synaptic activity as modeled by a decrease of R_m. Thepeak amplitudes of voltage transients at sites of brief, synaptic-likechanges in conductance were highly dependent on cell class andwere largest in Renshaw cells and smallest in motoneurons. Incombination with class-specific differences in the attenuationof transient voltage signals, this led to large differencesin the peak amplitudes of somatic voltage transients. Differencesin the rise times and half-widths of the voltage transientswere observed as well. Thus, based on passive properties, eachcell class has a unique set of input/output properties.

Address for reprint requests and other correspondence: T. Bui, Department of Physiology, Botterell Hall, Queen's University, Kingston K7L 3N6, Canada (E-mail: tuan{at}biomed.queensu.ca).

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