Arthropod touch reception: Spider hair sensilla as rapid touch detectors

被引：59

作者：

Albert J. ^{[1
]}

Friedrich O. ^{[1
]}

Dechant H.-E. ^{[1
,2
]}

Barth F. ^{[1
]}

机构：

[1] University of Vienna, Biocenter, Institute of Zoology, 1090 Wien

[2] Vienna University of Technology, Institute of Lightweight Structures and Aerospace Engineering, 1040 Wien

来源：

Journal of Comparative Physiology A | 2001年 / 187卷 / 4期

基金：

奥地利科学基金会;

关键词：

Arthropods; Biomechanics; Response characteristics; Tactile hairs; Touch reception;

D O I：

10.1007/s003590100202

中图分类号：

学科分类号：

摘要：

Wandering spiders like Cupiennius salei are densely covered by tactile hairs. In darkness Cupiennius uses its front legs as tactile feelers. We selected easily identifiable hairs on the tarsus and metatarsus which are stimulated during this behavior to study tactile hair properties. Both the mechanical and electrophysiological hair properties are largely independent of the direction of hair displacement. Restoring torques measure 10-9 to 10-8 Nm. The torsional restoring constant S changes non-linearly with deflection angle. It is of the order of 10-8 Nm/rad, which is about 10,000 times larger than for trichobothria. Angular thresholds for the generation of action potentials are ca.1°. Electrophysiology reveals a slow and a fast sensory cell, differing in adaptation time. Both cells are movement detectors mainly responding to the dynamic phase (velocity) of a stimulus. When applying behaviorally relevant stimulus velocities (up to 11 cm s-1) threshold deflection for the elicitation of action potentials and maximum response frequency are reached as early as 1.2 ms after stimulus onset and followed by a rapid decline of impulse frequency. Obviously these hairs inform the spider on the mere presence of a stimulus but not on details of its time-course and spatial orientation.

引用

页码：303 / 312

页数：9

共 22 条

[1]

Barth F.G., How to catch the wind: Spider hairs specialized for sensing the movement of air, Naturwissenschaften, 87, pp. 51-58, (2000)

[2]

Barth F.G., Sinne und Verhalten: aus dem Leben einer Spinne, (2001)

[3]

Barth F.G., Cordes D., Cupiennius remedius new species (Araneae, Ctenidae), and a key for the genus, J Arachnol, 26, pp. 133-141, (1998)

[4]

Barth F.G., Seyfarth E.-A., Bleckmann H., Schuch W., Spiders of the genus Cupiennius Simon1891 (Araneae, Ctenidae). I. Range distribution, dwelling plants, and climatic characteristics of the habitats, Oecologia, 77, pp. 187-193, (1988)

[5]

Barth F.G., Nakagawa T., Eguchi E., Vision in the ctenid spider Cupiennius salei: Spectral range and absolute sensitivity, J Exp Biol, 181, pp. 63-79, (1993)

[6]

Barth F.G., Wastl U., Humphrey J.A.C., Devarakonda R., Dynamics of arthropod filiform hairs. II. Mechanical properties of spider trichobothria (Cupiennius salei Keys.), Phil Trans R Soc Lond B, 340, pp. 445-461, (1993)

[7]

Dechant H.-E., Rammerstorfer F.G., Barth F.G., Arthropod touch reception: Stimulus transformation and finite element model of spider tactile hairs, J Comp Physiol A, 187, (2001)

[8]

Eckweiler W., Seyfarth E.-A., Tactile hairs and the adjustment of body height in wandering spiders: Behavior, leg reflexes and afferent projections in leg ganglia, J Comp Physiol A, 162, pp. 611-621, (1988)

[9]

Foelix R.F., Structure and function of tarsal sensilla in the spider Araneus diadematus, J Exp Zool, 175, pp. 99-124, (1970)

[10]

Foelix R.F., Mechano- and chemoreceptive sensilla, pp. 118-137, (1985)

← 1 2 3 →