Integration of Excitatory Postsynaptic Potentials in Dendrites of Motoneurons of Rat Spinal Cord Slice Cultures

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Integration of Excitatory Postsynaptic Potentials in Dendrites of Motoneurons of Rat Spinal Cord Slice Cultures

Matthew E. Larkum, Thomas Launey, Alexander Dityatev, and Hans-R. Lüscher

Department of Physiology, University of Bern, CH-3012 Bern, Switzerland

Larkum, Matthew E., Thomas Launey, Alexander Dityatev, and Hans-R. Lüscher. Integration of excitatory postsynapticpotentials in dendrites of motoneurons of rat spinal cord slicecultures. J. Neurophysiol. 80: 924-935, 1998. We examined theattenuation and integration of spontaneous excitatory postsynapticpotentials (sEPSPs) in the dendrites of presumed motoneurons (MNs)of organotypic rat spinal cord cultures. Simultaneous whole cellrecordings in current-clamp mode were made from either the somaand a dendrite or from two dendrites. Direct comparison of thetwo voltage recordings revealed that the membrane potentials atthe two recording sites followed each other very closely exceptfor the fast-rising phases of the EPSPs. The dendritic recordingrepresented a low-pass filtered version of the somatic recordingand vice versa. A computer-assisted method was developed to fitthe sEPSPs with a generalized $alpha$ -function for measuring their amplitudesand rise times (10-90%). The mean EPSP peak attenuation betweenthe two recording electrodes was determined by a maximum likelihoodanalysis that extracted populations of similar amplitude ratiosfrom the fitted events at each electrode. For each pair of recordings,the amplitude attenuation ratio for EPSP traveling from dendriteto soma was larger than that traveling from soma to dendrite.The linear relation between mean ln attenuation and distance betweenrecording electrodes was used to map 1/e attenuations into unitsof distance (µm). For EPSPs with typical time course travelingfrom the somatic to the dendritic recording electrode, the mean1/e attenuation corresponded to 714 µm; for EPSPs traveling inthe opposite direction, the mean 1/e attenuation correspondedto 263 µm. As predicted from cable analysis, fast EPSPs attenuatedmore in both the somatofugal and somatopetal direction than didslow EPSPs. For EPSPs with rise times shorter than ~2.0 ms, theattenuation factor increased steeply. Compartmental computer modelingof the experiments with biocytin-filled and reconstructed MNsthat used passive membrane properties revealed amplitude attenuationratios of the EPSP traveling in both the somatofugal and somatopetaldirection that were comparable to those observed in real experiments.The modeling of a barrage of sEPSPs further confirmed that thesomato-dendritic compartments of a MN are virtually isopotentialexcept for the fast-rising phase of EPSPs. Large, transient differencesin membrane potential are locally confined to the site of EPSPgeneration. Comparing the modeling results with the experimentssuggests that the observed attenuation ratios are adequately explainedby passive membrane properties alone.

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