Biology:Encarsia formosa

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Short description: Species of wasp

Encarsia formosa
Encarsia formosa.jpg
Scientific classification edit
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Hymenoptera
Family: Aphelinidae
Subfamily: Coccophaginae
Genus: Encarsia
Species:
E. formosa
Binomial name
Encarsia formosa
Gahan, 1924

Encarsia formosa is a species of chalcidoid wasp and a well known parasitoid of greenhouse whitefly, one of the first to be used commercially for biological pest control, from the 1920s. They can use at least 15 species of whitefly as a host, including Bemisia tabaci and Aleyrodes proletella.[1]

The tiny females (about 0.6 mm long) are black with a yellow abdomen and opalescent wings. This species reproduces asexually via thelytoky induced by Wolbachia infection.[1] Males are produced only rarely. They are slightly larger than females and are completely black in coloration.

Life cycle

Life cycles of greenhouse whitefly and its parasitoid wasp Encarsia formosa
Tomato leaf with whitefly nymphs (white) parasitized by E. formosa (black).

Females deposit 50-100 eggs individually inside the bodies of nymphs or pupae of the host species. The wasp larvae develop through four instars in about two weeks at optimum temperatures. Parasitized greenhouse whitefly pupae turn black in about 10 days, while parasitized sweet potato whiteflies turn amber brown. Both are easily distinguished from unparasitized host pupae. Wasp pupation occurs within the whitefly body. Adult wasps emerge about 10 days later.

Use in biological control

Encarsia formosa, a parasitoid, is sold commercially for biological control of whitefly, an insect pest of tomato and other horticultural crops.

Encarsia formosa has been used as a natural pesticide to control whitefly populations in greenhouses since the 1920s. Use of the insect fell out of fashion due to the increased prevalence of chemical pesticides and was essentially non-existent by the 1940s. Since the 1970s E. formosa has seen something of a revival, with renewed usage in European and Russian greenhouses.[1] In some countries, such as New Zealand, it is the primary biological control agent used to control greenhouse whiteflies, particularly on crops such as tomato, a particularly difficult plant for predators to establish on.[2]

Clap and fling flight

E. formosa utilizes the clap and fling mechanism often seen in sub-mm insects. The wings, at the apex, and nearly touching, fling apart and generate strong vortices along the leading edge and wing tips. This mechanism works well in low Reynolds number flight as the generated vortices remained attached through the stroke cycle. Flexible wings and bristles along the wing edges help mitigate the large drag forces that the insect must overcome. Unlike normal flight, this method would work in an entirely inviscid medium, as it does not rely on a starting vortex to create circulation about the wing.[3][4][5][6][7][8]

References

  1. 1.0 1.1 1.2 Hoddle, M. S.; Van Driesche, R. G.; Sanderson, J. P. (1998). "Biology and Use of the Whitefly Parasitoid Encarsia Formosa". Annual Review of Entomology 43 (1): 645–669. doi:10.1146/annurev.ento.43.1.645. PMID 15012401. http://www.biocontrol.ucr.edu/hoddle/ccbcdisk_g000027.pdf. 
  2. Bioforce Limited, New Zealand
  3. T. Weis-Fogh, Quick estimates of flight fitness in hovering animals, including novel mechanisms for lift production, J. Expl. Biol. 59, 169-230, 1973
  4. M. J. Lighthill, On the Weis-Fogh mechanism of lift generation, J. Fluid Mech. 60, 1-17, 1973
  5. Bennett, L. (1977). "Clap and fling aerodynamics- and experimental evaluation". Journal of Experimental Biology 69: 261–272. doi:10.1242/jeb.69.1.261. 
  6. Miller, L; Peskin, C.S. (2009). "Flexible clap and fling in tiny insect flight". The Journal of Experimental Biology 212 (19): 3076–3090. doi:10.1242/jeb.028662. PMID 19749100. 
  7. Santhanankrishnan, A.; Jones, S.; Low, A.A; Gadi, S.; Hedrick, T.L.; Miller, L. (2014). "Clap and fling mechanism with interacting porous wings in tiny insect flight.". The Company of Biologists: 3898–3909. 
  8. Lehmann, F.-O; Sane, S.P.; Dickinson; M. (2005). "The aerodynamics effects of wing-wing interaction in flapping insect wings". The Journal of Experimental Biology 208 (Pt 16): 3075–3092. doi:10.1242/jeb.01744. PMID 16081606. 

Wikidata ☰ Q614882 entry