Stiffness gradients facilitate ovipositor bending and spatial probing control in a parasitic wasp

• Published in: Journal of experimental biology Vol. 222; no. Pt 9
• Main Authors: Cerkvenik, Uroš, van Leeuwen, Johan L, Kovalev, Alexander, Gorb, Stanislav N, Matsumura, Yoko, Gussekloo, Sander W S
• Format: Journal Article
• Language: English
• Published: England 2019
• Subjects: Experimental Zoology; Experimentele Zoologie; Leerstoelgroep Experimentele zoölogie; WIAS; Ovipositor biomechanics; Steering mechanism; Hymenoptera; Material and structural properties
• ISSN: 0022-0949; 1477-9145
• DOI: 10.1242/jeb.195628

Many parasitic wasps use slender and steerable ovipositors to lay eggs in hosts hidden in substrates, but it is currently unknown how steering is achieved. The ovipositors generally consist of three longitudinally connected elements, one dorsal and two ventral valves that can slide along each other. For the parasitic wasp , it has been shown that protraction of the ventral valves causes incurving of the ventral valves towards the dorsal one, which results in a change in probing direction. We hypothesize that this shape change is due to differences in bending stiffness along the ovipositor. Alignment of the stiff tip of the dorsal valve with a more flexible ventral S-shaped region situated just behind the tip straightens this S-bend and results in upwards rotation of the ventral tip. We show that the S-shaped region of the ventral valves has a low bending stiffness because it contains soft materials such as resilin. In contrast, the large cross-sectional area of the dorsal valve tip area probably results in a high bending stiffness. Elsewhere, the dorsal valve is less stiff than the ventral valves. Our results support the hypothesis that the interaction between the stiff dorsal valve portion and the more flexible S-shaped region co-determines the configurational tip changes required for steering the ovipositor in any desired direction along curved paths in the substrate. This provides novel insights in the understanding of steering mechanisms of the hymenopteran ovipositor, and for application in man-made probes.