Neuronal firing properties and swimming motor patterns in young tadpoles of four amphibians: Xenopus , Rana , Bufo and Triturus

Abstract

We have compared intrinsic firing properties of motoneurons with the way they fire during locomotion in young tadpoles of four species of amphibian. Xenopus motoneurons have the highest current threshold for spiking; most fire a single spike to depolarising current steps; all fire reliably once per cycle during fictive swimming. Xenopus motoneurons recorded with Cs+-filled microlelectrodes fire repetitively to current but still fire only once per swimming cycle. Rana, Bufo and Triturus motoneurons have lower current thresholds; most fire bursts of spikes to suprathreshold current but most do not fire reliably during swimming and most still fire only once (if at all) per cycle. We conclude that neuronal firing patterns during locomotion cannot reliably be predicted from intrinsic firing properties, and suggest the composition and form of the underlying synaptic input is more important. We also measured cycle period, ventral root burst duration, and longitudinal delay during fictive swimming. These basic swimming parameters range from relatively long in Rana to relatively short in Xenopus. By discounting differences in neuronal firing properties between the four species, we can start to relate differences in fictive swimming to differences in synaptic drive, particularly the strong electrotonic input seen only in Xenopus.