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The Journal of Neurophysiology Vol. 82 No. 2 August 1999, pp. 687-699
Copyright ©1999 by the American Physiological Society
1The Nobel Institute for Neurophysiology, Department of Neuroscience, Karolinska Institutet, S-171 77 Stockholm, Sweden; 2A. N. Belozersky Institute of Physico-Chemical Biology, Moscow State University, Moscow 119 899, Russia; 3Institute of Neurobiology, Sun Juan, Puerto Rico 00901; and 4Institute of Information Transmission Problems, Russian Academy of Sciences, Moscow 101447, Russia
Deliagina, T. G.,
G. N. Orlovsky,
A. I. Selverston, and
Y. I. Arshavsky.
Neuronal Mechanisms for the Control of Body Orientation in
Clione I. Spatial Zones of Activity of Different Neuron
Groups. J. Neurophysiol. 82: 687-699, 1999. The marine mollusk Clione limacina,
when swimming, can stabilize different body orientations in the
gravitational field. Here we describe one of the modes of operation of
the postural network in Clione
maintenance of the
vertical, head-up orientation. Experiments were performed on the
CNS-statocyst preparation. Spike discharges in the axons of different
types of neurons were recorded extracellularly when the preparation was
rotated in space through 360° in different planes. We characterized
the spatial zones of activity of the tail and wing motor neurons as
well as of the CPB3 interneurons mediating the effects of statocyst
receptor cells on the tail motor neurons. It was found that the
activity of the tail motor neurons increased with deviation of the
preparation from the normal, rostral-side-up orientation. Their zones
of activity were very wide (~180°). According to the zone position,
three distinct groups of tail motor neuron (T1-T3) could be
distinguished. The T1 group had a center of the zone near the
ventral-side-up orientation, whereas the zones of T2 and T3 had their
centers near the left-side-up and the right-side-up positions,
respectively. By comparing the zone of activity with the direction of
tail bending elicited by each of the groups, one can conclude that
gravitational reflexes mediated by the T1, T2, and T3 groups will evoke
turning of the animal toward the head-up orientation. Two identified
wing motor neurons, 1A and 2A, causing the wing beating, were involved
in gravitational reactions. They were activated with the downward inclination of the ipsilateral side. Opposite reactions were observed in the motor neurons responsible for the wing retraction. A presumed motor effect of these reactions is an increase of oscillations in the
wing that is directed downward and turning of Clione
toward the head-up orientation. Among the CPB3 interneurons, at least four groups could be distinguished. In three of them (IN1, IN2, and
IN3), the zones of activity were similar to those of the three groups
(T1, T2, and T3) of the tail motor neurons. The group IN4 had the
center of its zone in the dorsal-side-up position; a corresponding group was not found among the tail motor neurons. In lesion
experiments, it was found that gravitational input mediated by a single
CPB3 interneuron produced activation of its target tail motor neurons in their normal zones, but the strength of response was reduced considerably. This finding suggests that several interneurons with
similar spatial zones converge on individual tail motor neurons. In
conclusion, because of a novel method, activity of the neuronal network
responsible for the postural control in Clione was
characterized in the terms of gravitational responses in different
neuron groups comprising the network.
This article has been cited by other articles:
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