Summary
-
1.
Recordings were made from efferent neurones in the posterior lateral line nerve, and from second order afferent neurones in the lateral line lobe of the medulla, in goldfish during gross stimulation of the spinal cord and selective stimulation of neurones in the medulla (including the Mauthner cells), which control active body movements.
-
2.
Brief bursts of 2–4 compound efferent action potentials were recorded from the proximal stump of the transected posterior lateral line nerve after a latency of 6–9 ms whenever either Mauthner neurone was excited, either antidromically by spinal cord stimulation, or by depolarizing current pulses injected into the Mauthner neurones through intracellular recording electrodes (Figs. 2 and 3).
-
3.
Other large neurones in the medulla, which were antidromically excited by spinal cord stimulation, also evoked efferent impulses in the lateral line nerves when they were selectively excited by the injection of depolarizing current pulses through the intracellular recording electrodes. Some of these neurones were injected with Procion yellow and identified as vestibular spinal and reticular spinal neurones.
-
4.
Latency measurements indicate that the lateral line efferent neurones are not electrically coupled to the vestibular and reticular spinal neurones.
-
5.
Spontaneous activity, and impulses evoked in second order afferent neurones in the lateral line lobe through mechanical stimulation of their sensory fields, or electrical stimulation of the posterior lateral line nerve, were inhibited for at least 40 ms after a latency of 10–12 ms following stimulation of either Mauthner cell. IPSPs with similar latency and duration and 4–6 mV in amplitude were recorded intracellularly from the second order afferent neurones. The duration of the inhibition coincides with the rapid phase of the “tail flip” elicited by Mauthner cell stimulation.
-
6.
Primitive Purkinje-like neurones in the crista cerebralis, which are also excited by lateral line stimulation, are not inhibited by Mauthner cell stimulation.
-
7.
Second order afferent neurones adapt to prolonged and/or excessive mechanical stimulation. If stimulation of the Mauthner cells is timed so that the responses of second order neurones to the first few cycles of phasic mechanical stimulation of their sensory fields are inhibited, then the adaptation, which is usually associated with the responses of the neurones to later phases of mechanical stimulation, is reduced.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Alnaes, E.: Unit activity of ganglionic and medullary second order neurones in the lateral line system. Acta physiol. scand.88, 160–174 (1973)
Bartlemez, G.W.: Mauthner's cell and nucleus motorius tegmenti. J. comp. Neurol.25, 87–128 (1915)
Caird, D.: The functional organization of the lateral line lobe in goldfish. Thesis: University of Sussex (1976)
Diamond, J.: The Mauthner Cell. In: Fish physiology, Vol. V (ed. W.S. Hoar, D.J. Randall), pp. 265–346. New York: Academic Press 1971
Dijkgraaf, S.: The functioning and significance of the lateral-line organs. Biol. Rev.38, 51–105 (1963)
Eccles, J.C., Llinas, R., Sasaki, K.: The excitatory synaptic actions of climbing fibres on the Purkinje cells of the cerebellum. J. Physiol. (Lond.)182, 268–296 (1966)
Flock, Å., Russell, I.J.: Efferent nerve fibres: Postsynaptic action on hair cells. Nature (Lond.), New Biol.243, 89–91 (1973a)
Flock, Å., Russell, I.J.: The postsynaptic action of efferent fibres in the lateral line organ of the burbot Lota lota. J. Physiol. (Lond.)235, 591–605 (1973b)
Furukawa, T.: Synaptic interaction at the Mauthner cell of goldfish. Progr. Brain Res.2, 46–70 (1966)
Gertychowa, R.: Studies on the ethology and space orientation of the blind cave fishAnoptichthys jordani Hubbs et Innes 1936 (Characidae). Folia Biol.18, 4–69 (1970)
Görner, P.: Independence of afferent activity from efferent activity in the lateral line organ ofXenopus laevis Daudin. In: Lateral line detection (ed. P. Cahn), pp. 199–214. Bloomington: Indiana University Press (1967)
Harris, G.G., Van Bergeijk, W.A.: Evidence that the lateral line organ responds to water displacements. J. acoust, Soc. Amer.34, 1831–1841 (1962)
Korn, H., Faber, D.S.: An electrically mediated inhibition in the goldfish medulla. J. Neurophysiol.38, 407–436 (1975 a)
Korn, H., Faber, D.S.: Inputs from the posterior lateral line nerves upon the goldfish Mauthner cell. I. Properties and synaptic localization of the excitatory component. Brain Res.96, 342–348 (1975b)
Llinas, R., Precht, W.: The inhibitory efferent system and its relation to the cerebellum in the frog. Exp. Brain Res.9, 16–29 (1969)
Paul, D., Roberts, B.L.: The efferent neurons of the anterior lateral line system in the dogfish: anatomical and electrophysiological identification. Brain Res. (in press)
Pearson, A.A.: The acoustico-lateral centers and the cerebellum with fiber connections of fishes. J. comp. Neurol.65, 201–294 (1936)
Precht, W., Richter, A., Ozawa, S., Shimazu, H.: Intracellular study of Frog's vestibular neurons in relation to labyrinth and spinal cord. Exp. Brain Res.19, 377–393 (1974)
Restieaux, N.J., Satchell, G.H.: A unitary study of the reticulo-motor system of the dogfish. J. comp. Neurol.109, 391–413 (1958)
Roberts, B.L.: Activity of lateral line sense organs in swimming dogfish. J. exp. Biol.56, 105–118 (1972)
Roberts, B.L., Russell, I.J.: The activity of lateral-line efferent neurons in stationary and swimming dogfish. J. exp. Biol.57, 435–448 (1972)
Russell, I.J.: The role of the lateral line efferent system inXenopus laevis. J. exp. Biol.54, 621–641 (1971)
Russell, I.J.: Central and peripheral inhibition of lateral line input during the startle response in goldfish. Brain Res.80, 517–522 (1974)
Russell, I.J., Roberts, B.L.: Active reduction of lateral-line sensitivity in swimming dogfish. J. comp. Physiol.94, 7–15 (1974)
Schmidt, R.S.: Amphibian acoustico-lateralis efferents. J. cell. comp. Physiol.65, 155–162 (1965)
Shelton, P.: The structure and function of the lateral line system in larvalXenopus laevis. J. exp. Zool.178, 211–231 (1971)
Schwartz, E.: Analysis of surface wave perception in some teleosts. In: Lateral line detection (ed. P. Cohn), pp. 123–134. Bloomington: Indiana University Press (1967)
Schwartz, E.: Lateral line receptors in fishes and amphibians. In: Handbook of sensory physiology, Vol. 111/3 (ed. A. Fessard), pp. 257–278. Berlin-Heidelberg-New York: Springer 1974
Suga, N., Shimizowa, T.: Site of neural attenuation of responses of self-vocalized sound in echolocating bats. Science183, 1211–1213 (1974)
Author information
Authors and Affiliations
Additional information
I thank Dr. B.L. Robarts for his helpful comments on the manuscript and Dr. M.F. for his help with filming the flip. This research was supported by a grant from the S.R.C.
Rights and permissions
About this article
Cite this article
Russell, I.J. Central inhibition of lateral line input in the medulla of the goldfish by neurones which control active body movements. J. Comp. Physiol. 111, 335–358 (1976). https://doi.org/10.1007/BF00606471
Received:
Issue Date:
DOI: https://doi.org/10.1007/BF00606471