Summary
-
1.
The cockroachPeriplaneta americana can modify the sensory activity received by its central nervous system from the cerci, paired abdominal wind-responsive appendages. Medial displacement of the cerci produces a reduction in the number of sensory action potentials (AP's) elicited by a wind stimulus (Fig. 2) (Libersat et al. 1987; Goldstein and Camhi 1988). This movement occurs naturally, for example during flying.
-
2.
This sensory reduction is present when measured as the integral of extracellularly recorded activity as well as when counting the number of AP's larger than a threshold voltage just larger than the background noise (Fig. 2C).
-
3.
Histological results confirm prior physiological experiments suggesting that the reduction may be produced by mechanical forces on the sensory nerve, rather than synaptically (Fig. 4).
-
4.
The wind-response of interneurons is significantly diminished by the sensory reduction when measured either extra- or intracellularly (Figs. 5, 6). Cells affected include identified ventral and dorsal giant interneurons (GI's), which carry directional information about wind from the abdominal cerci to the more anterior portions of the nervous system, and are involved in flying (Camhi 1980; Ritzmann 1984; Comer 1985).
-
5.
The reduction in the interneuronal response was unaffected by the elimination of input from descending central pathways, and input from a cereal chordotonal organ that senses cereal position and inhibits some of the GI's (Fig. 5). Thus, the reduction in wind-evoked sensory activity can itself account for the modulation of interneuron activity.
-
6.
The extracellularly recorded response of the nerve cord to wind was divided into: large action potentials (AP's) that included almost all of the GI AP's (Fig. 6B), and smaller AP's of unidentified cells. The activity of both small and large AP's is reduced by medial displacement of the cercus. However, the large AP's are significantly more reduced (Fig. 6). The small AP's comprise between one-half and two-thirds of the number of AP's recorded in response to wind.
-
7.
The sensory reduction may serve to protect the circuitry of the exquisitely sensitive wind-sensitive escape system from habituation by the strong winds generated when the animal flies.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Abbreviations
- GI :
-
giant interneuron
- AP :
-
action potential
References
Bacon JP, Altman JS (1977) A silver-intensification method for cobalt filled neurons in wholemount preparation. Brain Res 138:359–363
Bernard J, Gobin B, Callec JJ (1983) A chordotonal organ inhibits giant interneurons in the sixth abdominal ganglion of the cockroach. J Comp Physiol 153:377–383
Callec JJ, Guillet PC, Pinchon Y, Boistel J (1971) Further studies on synaptic transmission in insects. II. Relations between sensory information and its synaptic integration at the level of a single giant axon in the cockroach. J Exp Biol 55:123–149
Camhi JM (1980) The escape system of the cockroach. Sci Am 243:158–172
Comer C (1985) Analyzing cockroach escape behavior with lesions of individual giant interneurons. Brain Res 355:342–346
Comer CM, Dowd JP (1987) Escape turning behavior of the cockroach: changes in directionality induced by unilateral lesions of the abdominal nervous system. J Comp Physiol A 160:571–583
Dagan D, Parnas I (1970) Giant fiber and small fiber pathways involved in evasive response of the cockroachPeriplaneta americana. J Exp Biol 52:313–324
Daley DL, Delcomyn F (1980) Modulation of the excitability of cockroach giant interneurons during walking. I. Simultaneous excitation and inhibition. J Comp Physiol 138:231–239
Daley DL, Vardi N, Appignani B, Camhi JM (1981) Morphology of giant interneurons and cereal nerve projections of the American cockroach. J Comp Neurol 196:41–52
Goldstein RS, Camhi J (1988) Non-synaptic regulation of sensory activity during movement reduces wind-sensitive interneuron activity in the cockroach. Brain Res 440:366–369
Goldstein RS, Libersat F, Camhi JM (1987) Non-synaptic regulation of sensory feedback during movement. Soc Neurosci Abstr 13:398
Heusslein R, Gnatzy W (1987) Central projections of campaniform sensilla on the cerci of crickets and cockroaches. Cell Tissue Res 247:591–598
Kramer K, Markl H (1978) Flight-inhibition on ground contact in the American cockroachPeriplaneta americana. I. Contact receptors and a model of their central connections. J Insect Physiol 24:577–586
Krasne FB, Bryan JS (1973) Habituation: regulation through presynaptic inhibition. Science 182:589–592
Kullberg R (1987) Stretch-activated ion channels in bacteria and animal cell membranes. Trends Neurosci 10:387–388
Libersat F, Camhi JM (in press) Control of cereal position during flight in the cockroach: a mechanism for regulating sensory feedback. J Exp Biol
Libersat F, Goldstein RS, Camhi JM (1987) Nonsynaptic regulation of sensory activity during movement in cockroaches. Proc Natl Acad Sci USA 84:8150–8154
O'Shea M, Rowell CHF (1975) Protection from habituation by lateral inhibition. Nature 254:53–55
Ritzmann RE (1981) Motor responses to paired stimulation of giant interneurons in the cockroachPeriplaneta americana. II. The ventral giant interneurons. J Comp Physiol 143:71–80
Ritzmann R (1984) The cockroach escape response. In: Eaton RC (ed) Neural mechanisms of startle behavior. Plenum Press, New York, pp 93–131
Roeder K (1967) Nerve cells and insect behavior. Harvard University Press, Cambridge, Massachusetts
Westin J, Langberg JJ, Camhi JM (1977) Responses of giant interneurons of the cockroachPeriplaneta americana to wind puffs of different directions and velocities. J Comp Physiol 121:307–324
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Goldstein, R.S., Camhi, J.M. Modulation of activity in sensory neurons and wind-sensitive interneurons by cereal displacement in the cockroach. J. Comp. Physiol. 163, 479–487 (1988). https://doi.org/10.1007/BF00604902
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00604902