Ontogeny of electrophysiological properties and dendritic pattern in second-order chick vestibular neurons

The pattern of development of several subpopulations of second-order vestibular neurons was investigated by using intracellular recordings from chicken brain slices to define the timing of morphological and electrophysiological changes occurring at 3 critical ages. Two embryonic stages, embryonic day 13 (E13) and E15-16, and also newborn chicks were selected according to previous anatomical findings showing the differentiation of primary vestibular afferents and their synapses within a distinctive brainstem vestibular nucleus, the tangential nucleus. The responses of these cells to depolarizing and hyperpolarizing current pulses and their postsynaptic responses to vestibular nerve stimulation were recorded, while simultaneously biocytin was injected for subsequent morphogenetic analysis. From this study, developmental schedules of membrane properties, synaptic responses, and dendritic differentiation were established for the 2 cell populations of the tangential nucleus and other neurons located in the surrounding vestibular nuclei. Compared with all other second-order vestibular neurons, the principal cells of the tangential nucleus exhibited a distinctive schedule. Mainly, this includes their pattern of firing on depolarization, the shape and duration of the vestibular-evoked excitatory postsynaptic potential, and the time of onset of dendritic outgrowth. In regard to these observations, E15-16 appears to be a turning point in principal cell ontogeny, whereas these features occur earlier in development for other second-order vestibular neurons. These findings, which indicate that the principal cells may have distinct membrane properties at specific ages, are discussed in light of their unique vestibular innervation and the possible consequences for vestibular signal processing.