Generation of rhythmic patterns of activity by ventral interneurones in rat organotypic spinal slice culture

Abstract

1 In the presence of certain excitatory substances the rat isolated spinal cord generates rhythmic oscillations believed to be an in-built locomotor programme (fictive locomotion). However, it is unknown whether a long-term culture of the same tissue can express rhythmic activity. Such a simplified model system would provide useful data on the minimal circuitry involved and the cellular mechanisms mediating this phenomenon. For this purpose we performed patch clamp recording (under whole-cell voltage or current clamp conditions) from visually identified ventral horn interneurones of an organotypic slice culture of the rat spinal cord. 2 Ventral horn interneurones expressed rhythmic bursting when the extracellular [K⁺] was raised from 4 to 6-7 mM. Under voltage clamp this activity consisted of composite synaptic currents grouped into bursts lasting 0.9 ± 0.5 s (2.8 ± 1.5 s period) and was generated at network level as it was blocked by tetrodotoxin or low-Ca²⁺-high-Mg²⁺ solution and its periodicity was unchanged at different potential levels. 3 In current clamp mode bursting was usually observed as episodes comprising early depolarizing potentials followed by hyperpolarizing events with tight temporal patterning. Bursting was fully suppressed by 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) and reduced in amplitude and duration by N-methyl-D-aspartate (NMDA) receptor antagonism without change in periodicity. Extracellular field recording showed bursting activity over a wide area of the ventral horn. 4 Regular, rhythmic activity similar to that induced by K⁺ also appeared spontaneously in Mg²⁺-free solution. The much slower rhythmic pattern induced by strychnine and bicuculline was also accelerated by high-K⁺ solution. 5 The fast and regular rhythmic activity of interneurones in the spinal organotypic culture is a novel observation which suggests that the oversimplified circuit present in this culture is a useful model for investigating spinal rhythmic activity.