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The Tachinidae are a large and variable family of true flies within the insect order Diptera, with more than 8,200 known species and many more to be discovered. Over 1,300 species have been described in North America alone. Insects in this family commonly are called tachinid flies or simply tachinids. As far as is known, they all are protelean parasitoids, or occasionally parasites, of arthropods, usually other insects. The family is known from many habitats in all zoogeographical regions and is especially diverse in South America.[2]

Tachinidae
Temporal range: Eocene–Recent
Tachina fera
Scientific classification Edit this classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Diptera
(unranked): Eremoneura
(unranked): Cyclorrhapha
Section: Schizophora
Subsection: Calyptratae
Superfamily: Oestroidea
Family: Tachinidae
Bigot, 1853[1]
Subfamilies
Diversity
1,523 genera
"Tachinidae" by Harold Maxwell-Lefroy, 1909

Life cycle

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Reproductive strategies vary greatly between tachinid species, largely, but not always clearly, according to their respective life cycles. Many species are generalists rather than specialists.[3] Comparatively few are restricted to a single host species, so there is little tendency towards the close co-evolution one finds in the adaptations of many specialist species to their hosts, such as are typical of protelean parasitoids among the Hymenoptera.

Larvae (maggots) of most members of this family are parasitoids (developing inside a living host, ultimately killing it). In contrast, a few are parasitic (not generally killing the host). Tachinid larvae feed on the host tissues, either after having been injected into the host by the parent, or penetrating the host from outside. Various species have different modes of oviposition and of host invasion. Typically, tachinid larvae are endoparasites (internal parasites) of caterpillars of butterflies and moths, or the eruciform larvae of sawflies. For example, they have been found to lay eggs in African sugarcane borer larva, a species of moth common in sub-Saharan Africa,[4] as well as the more northerly Arctic woolly bear moth.[5] However, some species attack adult beetles and some attack beetle larvae. Others attack various types of true bugs, and others attack grasshoppers; a few even attack centipedes. Also parasitised are bees, wasps and sawflies.[6]

 
Tachinid eggs (possibly Trichopoda pennipes) on Leptoglossus occidentalis

Oviposition

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Probably the majority of female tachinids lay white, ovoid eggs with flat undersides onto the skin of the host insect. Imms[7] mentions the genera Gymnosoma, Thrixion, Winthemia, and Eutachina as examples. In a closely related strategy some genera are effectively ovoviviparous (some authorities prefer the term ovolarviparous[8]) and deposit a hatching larva onto the host. For example, this occurs in Tachinidae species which parasitize the butterfly Danaus chrysippus in Ghana.[9] The free larvae immediately bore into the host's body. Illustrative genera include Exorista and Voria. Many tachinid eggs hatch quickly, having partly developed inside the mother's uterus, which is long and often coiled for retaining developing eggs. However, it is suggested that the primitive state probably is to stick unembryonated eggs to the surface of the host.[8]

Many other species inject eggs into the host's body, using the extensible, penetrating part of their ovipositor, sometimes called the oviscapt, which roughly translates to "egg digger". Species in the genera Ocyptera, Alophora, and Compsilura are examples.

 
Istocheta aldrichi egg on Popillia japonica (Japanese beetle)
 
Most tachinids are dull colored, resembling house flies
 
Ormia ochracea, notable for its acute directional hearing[10]

In many species only one egg is laid on or in any individual host, and accordingly such an egg tends to be large, as is typical for eggs laid in small numbers. They are large enough to be clearly visible if stuck onto the outside of the host, and they generally are so firmly stuck that eggs cannot be removed from the skin of the host without killing them. Furthermore, scientists have observed in studies with the host cabbage looper that being glued to the host insect helps maggots burrow into the larva, where they remain until fully developed.[11]

Yet another strategy of oviposition among some Tachinidae is to lay large numbers of small, darkly coloured eggs on the food plants of the host species. Sturmia, Zenillia, and Gonia are such genera.

Many tachinids are important natural enemies of major insect pests, and some species actually are used in biological pest control; for example, some species of tachinid flies have been introduced into North America from their native lands as biocontrols to suppress populations of alien pests.[12] Conversely, certain tachinid flies that prey on useful insects are themselves considered as pests; they can present troublesome problems in the sericulture industry by attacking silkworm larvae. One particularly notorious silkworm pest is the Uzi fly (Exorista bombycis).

Another reproductive strategy is to leave the eggs in the host's environment; for example, the female might lay on leaves, where the host is likely to ingest them. Some tachinids that are parasitoids of stem-boring caterpillars deposit eggs outside the host's burrow, letting the first instar larvae do the work of finding the host for themselves. In other species, the maggots use an ambush technique, waiting for the host to pass and then attacking it and burrowing into its body.

Adult tachinids are not parasitic, but either do not feed at all or visit flowers, decaying matter, or similar sources of energy to sustain themselves until they have concluded their procreative activities. Their non-parasitic behaviour after eclosion from the pupa is what justifies the application of the term "protelean".

Description

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Tachinid flies mating

Tachinid flies are extremely varied in appearance. Some adult flies may be brilliantly colored and resemble blow-flies (family Calliphoridae). Most however are rather drab, some resembling house flies. However, tachinid flies commonly are more bristly and more robust. Also, they usually have a characteristic appearance. They have three-segmented antennae, a diagnostically prominent postscutellum bulging beneath the scutellum (a segment of the mesonotum). They are aristate flies, and the arista usually is bare, though sometimes plumose. The calypters (small flaps above the halteres) are usually very large. Their fourth long vein bends away sharply.[citation needed]

Adult flies feed on flowers and nectar from aphids and scale insects. As many species typically feed on pollen, they can be important pollinators of some plants, especially at higher elevations in mountains where bees are relatively few.

The taxonomy of this family presents many difficulties. It is largely based on morphological characters of the adult flies, but also on reproductive habits and on the immature stage.

As biological pest control

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Some tachinid flies parasitize pest species. This has allowed them to be used as biological control agents by farmers. Some Tachinidae are generalists; for instance, Compsilura concinnata uses, at least, 200 different hosts, and thus are less safe to be used as biological controls because they will attack non-pest species, resulting in population decline.[13] Others are more specialized and are safer; for instance, Istocheta aldrichi, which only attacks the Japanese beetle.[14][15][16]

Evolution

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This clade appears to have originated in the middle Eocene.[17] The oldest known putatively tachinid fossil (Lithexorista) dates from the Eocene Green River Formation in Wyoming.[18][19][20]

See also

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References

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  1. ^ Systema Dipterorum: Tachinidae
  2. ^ James E. O'Hara; Shannon J. Henderson (December 18, 2018). "World Genera of the Tachinidae (Diptera) and Their Regional Occurrence" (PDF).
  3. ^ John O. Stireman (2006). "Tachinidae: Evolution, Behavior, and Ecology". Annual Review of Entomology. 51: 525–555. doi:10.1146/annurev.ento.51.110104.151133. PMID 16332222.
  4. ^ Hastings, H.; Conling, D.E.; Graham, D.Y. (1988). "Notes on the natural host surveys and laboratory rearing of Goniozus natalensis Gordh (Hymenoptera: Bethylidae), a parasitoid of Eldana saccharina Walker (Lepidoptera: Pyralidae) larvae from Cyperus papyrus L. in Southern Africa" (PDF). Journal of the Entomological Society of Southern Africa. 51: 1.
  5. ^ Morewood, W. Dean; Wood, D. Monty (2002). "Host utilization byExorista thula Wood (sp. nov.) and Chetogena gelida (Coquillett) (Diptera: Tachinidae), parasitoids of arctic Gynaephora species (Lepidoptera: Lymantriidae)". Polar Biology. 25 (8): 575–582. Bibcode:2002PoBio..25..575M. doi:10.1007/s00300-002-0382-y. S2CID 20312863.
  6. ^ "Parasitic Flies - Ontario AppleIPM". www.omafra.gov.on.ca.
  7. ^ Imms' General Textbook of Entomology: Volume 1: Structure, Physiology and Development Volume 2: Classification and Biology. Berlin: Springer. 1977. ISBN 978-0-412-61390-6.
  8. ^ a b Wood, D. M. 1987. Chapter 110. Tachinidae. Pp. 1193-1269 in McAlpine, J.F., Peterson, B.V., Shewell, G.E., Teskey, H.J., Vockeroth, J.R. and D.M. Wood (eds.), Manual of Nearctic Diptera. Volume 2. Agriculture Canada Monograph 28: i-vi, 675-1332.
  9. ^ Edmunds, Malcolm (1976-03-01). "Larval mortality and population regulation in the butterfly Danaus chrysippus in Ghana". Zoological Journal of the Linnean Society. 58 (2): 129–145. doi:10.1111/j.1096-3642.1976.tb00823.x. ISSN 0024-4082.
  10. ^ Miles RN, Robert D, Hoy RR (1995). "Mechanically coupled ears for directional hearing in the parasitoid fly Ormia ochracea". The Journal of the Acoustical Society of America. 98 (6): 3059–3070. Bibcode:1995ASAJ...98.3059M. doi:10.1121/1.413830. PMID 8550933.
  11. ^ Brubaker, R. W. (1968-02-01). "Seasonal Occurrence of Voria ruralis a Parasite of the Cabbage Looper, in Arizona, and Its Behavior and Development in Laboratory Culture1". Journal of Economic Entomology. 61 (1): 306–309. doi:10.1093/jee/61.1.306. ISSN 0022-0493.
  12. ^ entomology.Wisconsin.edu. Compsilura concinnata, Parasitoid of Gypsy Moth
  13. ^ Young, Bruce E.; Auer, Stephanie; Ormes, Margaret; Rapacciuolo, Giovanni; Schweitzer, Dale; Sears, Nicole (5 October 2017). "Are pollinating hawk moths declining in the Northeastern United States? An analysis of collection records". PLOS ONE. 12 (10): e0185683. Bibcode:2017PLoSO..1285683Y. doi:10.1371/journal.pone.0185683. PMC 5628844. PMID 28982152.
  14. ^ O’Hara, J. Tachinidae Resources. Overview of the Tachinidae (Diptera)
  15. ^ Grenier, S. (1988-04-01). "Applied biological control with Tachinid flies (Diptera, Tachinidae): A review". Anzeiger für Schädlingskunde, Pflanzenschutz, Umweltschutz. 61 (3): 49–56. Bibcode:1988JPesS..61...49G. doi:10.1007/BF01906254. ISSN 0340-7330. S2CID 10085920.
  16. ^ Bugguide.net. Species Istocheta aldrichi - Winsome Fly
  17. ^ Zhao, Zhe; Su, Tian-Juan; Chesters, Douglas; Wang, Shi-di; Ho, Simon Y. W.; Zhu, Chao-Dong; Chen, Xiao-lin; Zhang, Chun-Tian (2013). "The Mitochondrial Genome of Elodia flavipalpis Aldrich (Diptera: Tachinidae) and the Evolutionary Timescale of Tachinid Flies". PLOS ONE. 8 (4): e61814. Bibcode:2013PLoSO...861814Z. doi:10.1371/journal.pone.0061814. PMC 3634017. PMID 23626734.
  18. ^ Townsend, C.H.T. (1921). "Some new muscoid genera ancient and recent". Insecutor Inscitiae Menstruus. 9: 132–134. Retrieved 26 June 2023.
  19. ^ Evenhuis, N.L. (1994). Catalogue of the fossil flies of the world (Insecta: Diptera). Leiden: Backhuys Publishers. pp. [i] + 1-600.
  20. ^ Cerretti, Pierfilippo; Stireman, John O.; Pape, Thomas; O’Hara, James E.; Marinho, Marco A. T.; Rognes, Knut; Grimaldi, David A. (2017-08-23). Friedman, Matt (ed.). "First fossil of an oestroid fly (Diptera: Calyptratae: Oestroidea) and the dating of oestroid divergences". PLOS ONE. 12 (8). Public Library of Science (PLoS): e0182101. Bibcode:2017PLoSO..1282101C. doi:10.1371/journal.pone.0182101. ISSN 1932-6203. PMC 5568141. PMID 28832610.
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