Electrical activity of neurons and development of the brain

Role of activity in the selection of new electrical synapses between adult Helisoma neurons

Our aim was to determine whether neural activity in the form of sodium-dependent action potentials play a role in the formation, maintenance and specificity of electrical synapses between regenerating neurons. We axotomized buccal neurons of the mollusc, Helisoma trivolvis, and placed ganglia into organ culture in the absence or presence of tetrodotoxin (TTX), a specific sodium channel blocker. Electrical coupling was measured using intracellular microelectrodes positioned within the soma of identified neurons. Neurite outgrowth was assessed by epifluorescence microscopy after filling neurons by iontophoresis with Lucifer yellow. Previous studies found that two days after axotomy transient electrical synapses form between heterologous neurons (e.g. buccal neurons 4 and 5). Five days after axotomy these transient connections disappeared and a new electrical synapse was stabilized between the paired buccal neurons 5. To determine whether blocking neural activity with TTX affected the specificity and formation of new electrical synapses, we examined electrical coupling between the heterologous neurons 4 and 5 two days after axotomy, and the paired buccal neurons 5 five days after axotomy. Our electrophysiological recordings indicated that different neurons in the buccal ganglion varied in their sensitivity to TTX (i.e. sensitivity of buccal neurons 19 greater than 5 greater than 4), but spontaneous activity was abolished in all 3 neurons by 2 x 10(-5) M TTX. Furthermore, the inhibitory effects of TTX occurred within seconds of superfusion and persisted for at least 6 days. Inhibition of activity by TTX could be reversed after superfusion with normal saline. Neurite outgrowth from axotomized neurons was not appreciably altered in the presence of TTX. Furthermore, no differences in the incidence of electrical coupling or the coupling resistance were detected between neurons 4 and 5 two days after axotomy and organ culture in the presence of TTX. However, electrical coupling between the symmetrically paired neurons 5 was elevated in the presence of TTX after 5 days. We conclude from these results that neural activity in the form of sodium-dependent action potentials does not play an important role in the formation or breaking of transient electrical synapses during neuronal regeneration in the mollusc Helisoma trivolvis.

Patterns of functional innervation in the auditory nuclei of the chick brainstem following early unilateral removal of the otocyst

Neurons in the third-order auditory nuclei in the brainstem of chicks (nuclei laminares, NL) receive functional innervation from the ipsilateral and contralateral second-order nuclei (nuclei magnocellulares, NM) which is restricted to the dorsal and ventral dendrites respectively. This pattern of innervation in NL is established by embryonic stage 40 (day 15 of incubation). We have examined the distribution of this innervation in both NL at this age or older in embryos from which one otocyst had been removed or damaged on day 3 of incubation. The distribution of functional synapses was determined by analysis of the changes in polarity of field potentials evoked by electrical stimulation of either the ipsilateral or contralateral NM. The distribution of field potential polarity in NL of 40% of recordings in operated embryos and in all sham-operated embryos was the same as that observed in unoperated embryos. However, in the remaining operated embryos, the time course of the field potentials and the changes in the polarity of the responses as the recording electrode penetrated NL were abnormal. The abnormal complexity of responses and the abnormal distribution of field potential amplitude in NL in the operated embryos suggests that loss or damage to the first-order auditory innervation can result in (a) the formation of novel, functional synapses between second-order auditory neurons, and/or (b) disruption of processes that produce segregated innervation of the dendrites of the third-order auditory neurons.

Lesion of the ponto-geniculo-occipital pathways in kittens. I. Effects on sleep and on unitary discharge of the lateral geniculate nucleus

Suppression of geniculate ponto-geniculo-occipital (PGO) waves was achieved in kittens by performing bilateral mesencephalic lesions of the PGO pathways. Sleep-wake parameters and the spontaneous unit activity in the lateral geniculate nucleus (LGN) were then chronically recorded during one month after the lesions. Whereas the states of vigilance remained normal, a significant reduction of the unitary discharge in the LGN during paradoxical sleep (PS) and particularly of its phasic component, was observed concomitantly with the suppression of PGO waves. It is concluded that phasic discharge of LGN neurons during PS is controlled by PGO-related mechanisms and that its suppression during the developmental period provides a model for studying its significance on brain maturation.

Attention to central and peripheral visual space in a movement detection task: an event-related potential and behavioral study. II. Congenitally deaf adults

We compared the effects of focussed attention upon event-related brain potentials (ERPs) to peripherally and centrally located visual stimuli in congenitally deaf subjects (Ss). The results were compared with those obtained from a group of normal hearing Ss in the same paradigm. ERPs from deaf and hearing Ss displayed similar attention-related changes with attention to the centrally located stimuli. These included enhanced amplitudes of the N1 component (157 ms) over the occipital regions of both hemispheres. By contrast, with attention to peripheral visual stimuli, ERPs from deaf Ss displayed attention-related increases that were several times larger than those from hearing Ss and different in scalp distribution. Whereas for hearing Ss the principal effects of attention to peripheral stimuli occurred over the contralateral parietal region, in deaf Ss the effects were also observed over the occipital regions of both hemispheres. In addition, lateral asymmetries in behavior and the ERPs indicated a greater role for the right hemisphere in this task in hearing Ss, but predominance of the left hemisphere in deaf Ss. These results suggest that auditory deprivation since birth has major effects on the development of the peripheral visual system. The specific pattern of group differences is discussed in relation to other studies of the effects of unimodal deprivation on the development of remaining modalities.

Early development of voltage-dependent sodium currents in cultured mouse spinal cord neurons

Spinal cord neurons were dissociated from 13-day embryonic mice and grown in culture for 1-28 days. Sodium currents of neurons in culture for 1-2 days were compared with those in culture for 2-4 weeks, using the whole-cell voltage clamp method. Rapid neurite outgrowth created space clamp limitations so that unclamped neuritic sodium action potentials prevented accurate analysis of sodium current properties. Therefore neurons were bathed in sodium-free solution and brief puffs of sodium were delivered to the cell soma so that only somatic sodium currents were recorded. Sodium currents of neurons at 1-2 days in culture had voltage-dependent activation and inactivation characteristic of these channels, both in mature cultured spinal neurons and in other preparations. However, the estimated channel density on the soma of neurons 1-2 days in culture was less than two channels per micron2. Since the available sodium conductance (as measured by action potential rise rates) increases during development of spinal cord neurons in culture (Westbrook and Brenneman, 1984), we suggest that changes in channel density and/or distribution, rather than in channel kinetics, may underlie the increase in sodium conductance.