Sensory Coding For Feeding Deterrence in the Grasshopper Schistocerca Americana

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Journal of Experimental Biology 158,241-259 (1991)
Published by Company of Biologists 1991

Sensory Coding For Feeding Deterrence in the Grasshopper Schistocerca Americana

R. F. CHAPMAN ¹, A. ASCOLI-CHRISTENSEN ¹, and P. R. WHITE ²

¹ Division of Neurobiology, University of Arizona Tucson, AZ 85721, USA
² Department of Zoology, University of Oxford, Oxford OX1 3PS, UK

The electrophysiological responses of sensilla on the tibiaof Schistocerca americana (Drury) to six compounds were examined.All the compounds were shown to cause feeding deterrence athigh concentrations. Nicotine hydrogen tartrate, quinine, hordenine(all alkaloids) and salicin (a phenolic glycoside) all stimulatedone cell in each sensillum. This was shown by differential adaptationexperiments to be the same cell. In some sensilla this cellalso responded to linamarin (a cyanogenic glycoside). Earlierwork had shown that the activity of this cell was correlatedwith feeding deterrence. However, canavanine (a nonprotein aminoacid) did not stimulate this cell, although it caused feedingdeterrence. All the compounds, except salicin, produced a markeddepression in the activity of cells responding to sucrose, andat higher concentrations of the compounds this inhibition wasalmost complete.

The activity of the deterrent cell and inhibitionof the activity of sucrose-sensitive cells appear to act togetherto produce the behavioural effects of most chemicals, but canavanineappears to act only by suppressing the activity of other cellsand salicin primarily through activity of the deterrent cell.In addition, quinine disrupts the activity of all the cellsand in its presence the deterrent cell adapts very slowly sothat the message signalling deterrence is sustained.

At lowconcentrations, salicin, and probably hordenine, increased theduration of feeding. In the case of hordenine this was due toan increase in the firing rate of sucrose-sensitive neurones;with salicin the increase was associated with a high thresholdof response and a rapid rate of adaptation of the deterrentcell.

Thus, similar behavioural effects are produced by a varietyof sensory phenomena with each compound acting in a slightlydifferent manner from the others.

Key words: chemoreception, deterrence, sensory inhibition, Schistocerca americana

Accepted on February 11, 1991

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