Abstract
Like many flightless, obligatory walking insects, the stick insect Carausius morosus makes intensive use of active antennal movements for tactile near range exploration and orientation. The antennal joints of C. morosus have a peculiar oblique and non-orthogonal joint axis arrangement. Moreover, this arrangement is known to differ from that in crickets (Ensifera), locusts (Caelifera) and cockroaches (Blattodea), all of which have an orthogonal joint axis arrangement. Our hypothesis was that the situation found in C. morosus represents an important evolutionary trait of the order of stick and leaf insects (Phasmatodea). If this was true, it should be common to other species of the Phasmatodea. The objective of this comparative study was to resolve this question. We have measured the joint axis orientation of the head–scape and scape–pedicel joints along with other parameters that affect the tactile efficiency of the antenna. The obtained result was a complete kinematic description of the antenna. This was used to determine the size and location of kinematic out-of-reach zones, which are indicators of tactile acuity. We show that the oblique and non-orthogonal arrangement is common to eight species from six sub-families indicating that it is a synapomorphic character of the Euphasmatodea. This character can improve tactile acuity compared to the situation in crickets, locusts and cockroaches. Finally, because molecular data of a recent study indicate that the Phasmatodea may have evolved as flightless, obligatory walkers, we argue that the antennal joint axis arrangement of the Euphasmatodea reflects an evolutionary adaptation to tactile near range exploration during terrestrial locomotion.
This is a preview of subscription content, log in via an institution to check access.
References
Bradler S (2003) Phasmatodea, Gespenstschrecken. In: Dathe HH (ed) Lehrbuch der speziellen Zoologie Bd. I: Wirbellose Tiere, 5. Teil: Insecta. Spektrum, Heidelberg, Berlin pp251–260
Bradley JC, Galil BS (1977) The taxonomic arrangement of the Phasmatodea with keys to the subfamilies and tribes. Proc Entomol Soc Wash 79:176–208
Cameron SL, Barker SC, Whiting MF (2006) Mitochondrial genomics and the new insect order Mantophasmatodea. Mol Phylogenet Evol 38:274–279
Dürr V, König Y, Kittmann R (2001) The antennal motor system of the stick insect Carausius morosus: anatomy and antennal movement pattern during walking. J Comp Physiol [A] 187:131–144
Gewecke M (1972) Bewegungsmechanismus und Gelenkrezeptoren der Antennen von Locusta migratoria L. (Insecta, Orthoptera). Z Morphol Tiere 71:128–149
Honegger H-W (1981) A preliminary note on a new optomotor response in crickets: antennal tracking of moving targets. J Comp Physiol A 142:419–421
Krause AF, Dürr V (2004) Tactile efficiency of insect antennae with two hinge joints. Biol Cybern 91:168–181
Okada J, Toh Y (2004) Spatio-temporal patterns of antennal movements in the searching cockroach. J Exp Biol 207:3693–3706
Staudacher E, Gebhardt M, Dürr V (2005) Antennal movements and mechanoreception: neurobiology of active tactile sensors. Adv Insect Physiol 32:49–205
Whiting MF, Bradler S, Maxwell T (2003) Loss and recovery of wings in stick insects. Nature 421:264–267
Zakotnik J, Matheson T, Dürr V (2004) A posture optimisation algorithm for model-based motion capture of movement sequences. J Neurosci Methods 135:43–54
Acknowledgements
The authors thank Sven Bradler (Göttingen) for the phylogenetic advice and supply of the species A. festinatum and P. phalangiphora.
Author information
Authors and Affiliations
Corresponding author
Electronic supplementary material
Below is the link to the electronic supplentary material.
Fig. S1
Size and joint angle range ratios. Left: The relative length of the antennae and front legs affects the efficiency of tactual obstacle detection during locomotion. In R. artemis, M. extradentata and females of E. tiaratum, the antennae are much shorter than the front legs (blue ellipse). In all other species, the antennae reach as far as or further than the front legs (mean ?plusmn; SD; n 1: see Table 1). Right: The passive joint angle range of the SP joint is larger than that of the HS joint. It is particularly large in animals that rest their antennae on their back (red ellipse). In species with short antennae (blue ellipse) the ratio of SP range to HS range tends to be larger than in species with long antennae. The Heteropteryginae (grey ellipse) have the largest angular range (mean ± SD; n 2: see Table 1 (JPG 92,318 kb).)
Fig. S2
Cladogram. Slanted and non-orthogonal antennal joint axes are common to the Euphasmatodea. This character improves tactile acuity. Phasmatodea are predominantly nocturnal, wingless obligatory walkers with long antennae. Saltatoria and Blattodea have orthogonal axes aligned with the sagittal and horizontal plane (JPG 103,479 kb).
Rights and permissions
About this article
Cite this article
Mujagic, S., Krause, A.F. & Dürr, V. Slanted joint axes of the stick insect antenna: an adaptation to tactile acuity. Naturwissenschaften 94, 313–318 (2007). https://doi.org/10.1007/s00114-006-0191-1
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00114-006-0191-1