Some four-winged insect orders, such as the Lepidoptera, have developed a wide variety of morphological wing coupling mechanisms in the imago which render these taxa as "functionally dipterous" (effectively two-winged) for efficient insect flight.[1] All but the most basal forms exhibit this wing coupling.[2]: 4266
The mechanisms are of three different types - jugal, frenulo-retinacular and amplexiform.[3]
Jugal wing coupling
editThe more primitive groups of moth have an enlarged lobe-like area near the basal posterior margin, i.e. at the base of the forewing, called jugum, that folds under the hindwing in flight.[2][4]: 631–664
Frenulo-retinacular wing coupling
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Other groups of moth have a frenulum on the hindwing that hooks under a retinaculum on the forewing.[4] The retinaculum is a hook or tuft on the underside of the forewing of some moths. Along with the frenulum, a spine at the base of the forward or costal edge of the hindwing, it forms a coupling mechanism for the front and rear wings of the moth.
Amplexiform wing coupling
editIn the butterflies[a] and in the Bombycoidea[b], there is no arrangement of frenulum and retinaculum to couple the wings. Instead, an enlarged humeral area of the hindwing is broadly overlapped by the forewing. Despite the absence of a specific mechanical connection, the wings overlap and operate in phase. The power stroke of the forewing pushes down the hindwing in unison. This type of coupling is a variation of frenate type but where the frenulum and retinaculum are completely lost.[1][5]
Hamuli wing coupling
editHamuli wing coupling is a mechanism unique to winged Hymenoptera. The hamuli consist of hook-like setae arrayed along the leading edge of the hind wing that engage with the recurved trailing edge (the retinaculum) of the fore wing during flight, uniting both wings into a single functional wing[6].
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leafcutter bee taking flight from Great Valley gumplant. The front and rear wings hook together on the first wing stroke. 6,000 fps played at 30 fps.]] and repeated at eight frames a second
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leafcutter bee taking flight from Great Valley gumplant. Its left pair of wings have not hooked together resulting in the hind wing not contributing to lift and the bee holding its legs to the right
Notes
edit- ^ The male of one species of hesperiid (skipper) butterfly does have wing couplings.
- ^ The Sphingidae (hawk moths) however do have wing couplings.
References
edit- ^ a b Dudley, Robert (2002). The biomechanics of insect flight: form, function, evolution (Reprint, illustrated ed.). Princeton University Press. p. 476. ISBN 978-0-691-09491-5.
- ^ a b Stocks, Ian (2008). "Wing coupling". In Capinera, John L. (ed.). Encyclopedia of Entomology. Gale virtual reference library. Vol. 4 (2 ed.). Springer Reference. p. 4345. ISBN 978-1-4020-6242-1. Retrieved 14 November 2010.
- ^ Scoble, M.J. (1995). The Lepidoptera: form, function and diversity (Reprint (illustrated) ed.). Oxford University Press. p. 416. ISBN 978-0-19-854952-9. Retrieved 14 November 2010. Subsec. "Wing coupling". Pp 56-60.
- ^ a b Powell, Jerry A. (2009). "Lepidoptera". In Resh, Vincent H.; Cardé, Ring T. (eds.). Encyclopedia of Insects (2 (illustrated) ed.). Academic Press. p. 1132. ISBN 978-0-12-374144-8. Retrieved 14 November 2010.
- ^ Gorb, Stanislav (2001). "Inter-locking of body parts". Attachment devices of insect cuticle. Springer. p. 305. ISBN 978-0-7923-7153-3. Retrieved 16 November 2010.
- ^ Basibuyuk, H. H.; Quicke, D. L. J. (1997). "Hamuli in the Hymenoptera (Insecta) and their phylogenetic implications". Systematic Entomology. 22 (3): 273–292.
Sources
edit- Pinhey, E (1962). Hawk Moths of Central and Southern Africa. Longmans Southern Africa, Cape Town.