Summary
Cupiennius salei (Ctenidae) is a tropical wandering spider which lives in close association with a particular type of plant (see companion paper). These plants are the channels through which the spiders receive and emit various types of vibrations. We measured the vibrations the spiders are typically exposed to when they sit on their dwelling plants (banana plant, bromeliad) in their natural biotope in Central America. In addition a laboratory analysis was carried out to get an approximate idea of the complex vibration-propagating properties of the dwelling plants, taking a banana plant as an example. (1) Types of vibrations (Figs. 1–4). Despite variability in detail there are characteristic differences in spectral composition between the vibrations of various abiotic and biotic origins: (a) Vibrations due to wind are very low frequency phenomena. Their frequency spectra are conspicuously narrow with prominent peaks close to or, more often, below 10 Hz. Vibrations due to raindrops show maximal acceleration values at ca. 1000 Hz. Their frequency band at-20 dB extends up to ca. 250 Hz where-as that of the vibrations due to wind extends to only ca. 50 Hz. (b) The frequency spectra of prey vibrations such as those generated by a running cockroach are typically broad-banded and contain high frequencies; they have largest peaks mostly between ca. 400 and 900 Hz. Their-20 dB frequency bands usually extend from a few Hz to ca. 900 Hz. Some potential prey animals such as grass-hoppers seem to be vibrocryptic; they walk by the spider as if unnoticed. Their “cautious” gait leads to only weak vibrations at very low frequencies resembling the background noise due to wind. Courtship signals are composed maily of low frequencies, intermediate between background noise and prey vibrations (male: prominent peaks at ca. 75 Hz and ca. 115 Hz; female: dominant frequencies between ca. 20 Hz and ca. 50 Hz). The male signal is composed of “syllables” and differs from all other vibrations studied here by being temporally highly ordered. A comparison with previous electrophysiological studies suggests that the high pass characteristics of the vibration receptors enhance the signal-to-(abiotic)-noise ratio and that the vibration-sensitive interneurons so far examined and found to have band pass characteristics are tuned to the frequencies found in the vibrations of biotic origin. (2) Signal propagation (Fig. 5). In terms of frequency-dependent attenuation of vibrations the banana plant is well suited for transmitting the above signals. Average attenuation values are ca. 0.35 dB/cm. Together with known data on vibration receptor sensitivity this explains the range of courtship signals of more than 1 m observed in behavioral studies. Attenuation in the plant is neither a monotonic function of frequency nor of distance from the signal source.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Barth FG (1982) Spiders and vibratory signals: sensory reception and behavioral significance. In: Witt PN, Rovner JS (eds) Spider communication: mechanisms and ecological significance. Princeton University Press, Princeton, NJ, pp 67–122
Barth FG (1985) Neuroethology of the spider vibration sense. In: Barth FG (ed) Neurobiology of arachnids. Springer, Berlin Heidelberg New York Tokyo, pp 203–229
Barth FG (1986) Vibrationssinn und vibratorische Umwelt von Spinnen. Naturwissenschaften 73:519–530
Barth FG, Geethabali (1982) Spider vibration receptors: threshold curves of individual slits in the metatarsal lyriform organ. J Comp Physiol 148:175–185
Barth FG, Seyfarth E-A (1979) Cupiennius salei Keys. (Araneae) in the highlands of Central Guatemala. J Arachnol 7:255–263
Barth FG, Seyfarth E-A, Bleckmann H, Schüch W (1988) Spiders of the genus Cupiennius Simon 1891 (Araneae, Ctenidae). I. Range distribution, dwelling plants, and climatic characteristics of the habitats. Oecologia 77:187–193
Bleckmann H, Barth FG (1984) Sensory ecology of a semiaquatic spider (Dolomedes triton). II. The release of predatory behavior by water surface waves. Behav Ecol Sociobiol 14:303–312
Bleckmann H, Rovner JS (1984) Sensory ecology of a semiaquatic spider (Dolomedes triton). I. Roles of vegetation and wind-generated waves in site selection. Behav Ecol Sociobiol 14:297–301
Bohnenberger J, Seyfarth E-A, Barth FG (1983) A versatile feedback controller for electromechanical stimulation devices. J Neurosci Meth 9:335–341
Brüssel A (1987) Belastungen und Dehnungen im Spinnenskelett unter natürlichen Verhaltensbedingungen. Dissertation, JW Goethe-Universität, Frankfurt am Main
Hergenröder R, Barth FG (1983) The releaseof attack and escape behavior by vibratory stimuli in a wandering spider (Cupiennius salei Keys). J Comp Physiol 152:347–358
Hoffmaster DK (1982) Responses of the spider Argiope aurantia to low frequency phasic and continuous vibrations. Animal Behav 30:123–127
Kalmijn A (1987) Hydrodynamic and acoustic field detection. In: Atema J, Fay RR, Popper AN, Tavolga W (eds) Sensory biology of aquatic animals. Springer, Berlin Heidelberg New York Tokyo, pp 83–130
Keuper A, Kühne R (1983) The acoustic behavior of the bushcricket Tettigonia cantans. II. Transmission of airborne-sound and vibration signals in the biotope. Behav Proc 8:125–145
Klärner D, Barth FG (1982) Vibratory signals and prey capture in orb-weaving spiders. J Comp Physiol 148:445–455
Liesenfeld FJ (1956) Untersuchungen am Netz und über den Erschütterungssinn von Zygiella x-notata (Cl) (Araneidae). Z Vergl Physiol 38:563–592
Masters MW (1984a) Vibrations in the orb web of Nuctenea sclopetaria (Araneidae). I. Transmission through the web. Behav Ecol Sociobiol 15:207–215
Masters MW (1984b) Vibrations in the orb web of Nuctenea sclopetaria (Araneidae). II. Prey and wind signals and the spider's response threshold. Behav Ecol Sociobiol 15:217–223
Michelsen A, Fink F, Gogala M, Traue D (1982) Plants as transmission channels for insect vibrational songs. Behav Ecol Sociobiol 11:269–281
Rovner JS, Barth FG (1981) Vibratory communication through living plants by a tropical wandering spider. Science 214:464–466
Schüch W, Barth FG (1985) Temporal patterns in the vibratory courtship of a wandering spider (Cupiennius salei Keys). Behav Ecol Sociobiol 16:263–271
Speck J, Barth FG (1982) Vibration sensitivity of pretarsal slit sensilla in the spider leg. J Comp Physiol 148:187–194
Speck-Hergenröder J, Barth FG (1987) Tuning of vibration sensitive neurons in the central nervous system of a wandering spider, Cupiennius salei Keys. J Comp Physiol A 160:467–475
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Barth, F.G., Bleckmann, H., Bohnenberger, J. et al. Spiders of the genus Cupiennius Simon 1891 (Araneae, Ctenidae). Oecologia 77, 194–201 (1988). https://doi.org/10.1007/BF00379186
Received:
Issue Date:
DOI: https://doi.org/10.1007/BF00379186