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Link to original content: http://en.m.wikipedia.org/wiki/Tegula_(insect_anatomy)
Tegula (insect anatomy) - Wikipedia

Tegula (insect anatomy)

A tegula is a small sclerite situated above the base of the costal vein in the wings of various insects such as Orthoptera, Lepidoptera, Hymenoptera, Diptera, and Auchenorrhyncha, and attached to the antero-lateral portion of the mesonotum.[1] It is densely innervated, with sensory bristles, campaniform sensilla, as well as a chordotonal organ in some species.[2]

The tegula in locusts is a model system for studying the role of feedback from mechanoreceptors during movement.[3][4][5] In locusts, the tegula directly controls flight muscles. The motor neurons that control the activation of wing elevator muscles are phase-locked to the neurons that innervate the tegula such that when the tegula is electrically stimulated the elevator muscles initiate an upstroke.[6] When the tegula is removed, locust flight is clumsy and disordered at first but most animals adapt, suggesting the use of other mechanoreceptors to control flight.[7][8][9]

The tegula system is also a model for studying the role of neuromodulation for state-dependent motor control. Neural signals from the tegula only initiate wing muscle contraction when the animal is in flight (or fictive flight) due to endogenous release of the neuromodulator octopamine.[10] This mechanism ensures that the animal does not initiate a wing stroke if the bristles are deflected by wind as the animal is walking.

The tegula is labeled f on this chalcid. Click for an uncropped version.

References

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  1. ^ Fischer, Wolf and Büschges. "The locust tegula: kinematic parameters and activity pattern during the wing stroke". Journal of Experimental Biology. Retrieved 2010-08-31.
  2. ^ Fudalewicz-Niemczyk, Władysława (1963). L'innervation et les organes sensoriels des ailes des Diptères et comparaison avec l'innervation des ailes d'insectes d'autres ordres.
  3. ^ Ramirez, J. M., & Pearson, K. G. (1993). Alteration of bursting properties in interneurons during locust flight. Journal of neurophysiology, 70(5), 2148-2160.
  4. ^ Pearson, K. G. and Wolf, H. Connections of hindwing tegulae with flight neurones in the locust, Locusta migratoria. J. Exp. Biol. 135:381-409, 1988
  5. ^ Wolf, H. "The Locust Tegula: significance for flight rhythm generation, wing movement control and aerodynamic force production." Journal of Experimental Biology 182.1 (1993): 229-253.
  6. ^ Wolf, H. "The Locust Tegula: significance for flight rhythm generation, wing movement control and aerodynamic force production." Journal of Experimental Biology 182.1 (1993): 229-253.
  7. ^ Recovery of the flight system following ablation of the tegulae in immature adult locusts, C Gee, R Robertson, Journal of Experimental Biology 1996 199: 1395-1403.
  8. ^ Kien, J., Altman, J.S. Connections of the locust wing tegulae with metathoracic flight motoneurons. J. Comp. Physiol. 133, 299–310 (1979). https://doi.org/10.1007/BF00661132
  9. ^ Büschges, A., & Pearson, K. G. (1991). Adaptive modifications in the flight system of the locust after the removal of wing proprioceptors. Journal of Experimental Biology, 157(1), 313-333.
  10. ^ Ramirez, J. M., & Pearson, K. G. (1991). Octopaminergic modulation of interneurons in the flight system of the locust. Journal of Neurophysiology, 66(5), 1522-1537.