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Not evaluated (IUCN 3.1)
The housefly (also house fly, house-fly or common housefly), Musca domestica, is a fly of the suborder Cyclorrhapha. It is believed to have evolved in the Cenozoic era, possibly in the Middle East, and has spread all over the world. It is the most common fly species found in habitations. Adult insects are grey to black with four dark longitudinal lines on the thorax, slightly hairy bodies and a single pair of membranous wings. They have red eyes, and the slightly larger female has these set further apart than the male.
The female housefly usually only mates once and stores the sperm for later use. She lays batches of about 100 eggs on decaying organic matter such as garbage, carrion or feces. These soon hatch into legless white maggots which after 2 to 5 days of development transform into reddish-brown pupae, about 8 mm (0.3 in) long. Adult flies normally live for 2 to 4 weeks but can hibernate during the winter. The adults feed on a variety of liquid or semi-liquid substances beside solid materials which have been softened by saliva. They carry pathogens on their bodies and in their feces and can contaminate food and contribute to the transfer of food-borne illnesses. For these reasons they are considered pests, but have been used in the laboratory in research into ageing and sex determination.
Adult houseflies grow to 8–12 millimetres (0.3–0.5 in) long. The thorax is gray or sometimes even black, with four longitudinal dark lines on the back. The whole body is covered with hair-like projections. The females are slightly larger than the males, and have a much larger space between their red compound eyes.
Pupae can range from about 8 to 20 mg under different conditions.
Like other Diptera (meaning "two-winged"), houseflies have only one pair of wings; what would be the hind pair is reduced to small halteres that aid in flight stability. Characteristically, the media vein (M1+2 or fourth long vein of the wing) shows a sharp upward bend.
Species that appear similar to the housefly include:
- The lesser house fly, Fannia canicularis, is smaller, more slender, and the media vein is straight.
- The stable fly, Stomoxys calcitrans, has piercing mouthparts and the media vein is only slightly curved.
The mouth parts of the fly are characterised by the proboscis, a tubular protrusion found on the anterior end of many insects. At the end of the proboscis, the labium is found. The structure is a sponge-like organ that is characterised by many groves, called pseudotrachae. The purpose of this pseudotrachea is to take up liquids. The absorbed liquid is eventually transported to the oesophagus.
Each female fly can lay up to 500 eggs in a lifetime, in several batches of about 75 to 150. The eggs are white and are about 1.2 mm in length. Within a day, larvae (maggots) hatch from the eggs; they live and feed on (usually dead and decaying) organic material, such as garbage, carrion, or feces. They are pale-whitish, 3–9 mm long, thinner at the mouth end, and legless. Their life cycle ranges from two weeks to three months. At the end of their fourth instar, the maggots crawl to a dry, cool place and transform into pupae, coloured reddish or brown and about 8 mm long. The adult flies then emerge from the pupae. (This whole cycle is known as complete metamorphosis.) The adults live from two weeks to a month in the wild, or longer in benign laboratory conditions. Having emerged from the pupae, the flies cease to grow; small flies are not necessarily young flies, but are instead the result of getting insufficient food during the larval stage.
Some 36 hours after having emerged from the pupa, the female is receptive for mating. The male mounts her from behind to inject sperm. Copulation takes a few seconds to a couple of minutes. Normally, the female mates only once, storing the sperm to use it repeatedly for laying several sets of eggs.
The flies depend on warm temperatures; generally, the warmer the temperature, the faster the flies will develop.
Because the somatic tissue of the housefly consists of long-lived post-mitotic cells, it can be used as an informative model system for understanding cumulative age-related cellular alterations. Agarwal and Sohal studied the level of the oxidative DNA damage 8-hydroxydeoxyguanosine (8-OHdG) in houseflies. They found that the level of 8-OHdG increased with age of the flies. They also found an inverse association of 8-OHdG level with life expectancy of the flies. They concluded that their results support the hypothesis that oxidative molecular damage is a causal factor in senescence (aging). These findings are in accord with the general view that oxidative DNA damage, particularly in post-mitotic tissues, is a principal cause of aging. (Also see DNA damage theory of aging.)
The housefly is an object of biological research, mainly because of one remarkable quality: the sex determination mechanism. Although a wide variety of sex determination mechanisms exist in nature (e.g. male and female heterogamy, haplodiploidy, environmental factors), the way sex is determined is usually fixed within one species. The housefly is thought to exhibit several different mechanisms for sex determination, such as male heterogamy (like most insects and mammals), female heterogamy (like birds) and maternal control over offspring sex. The exact mechanism of sex determination in the housefly is, however, still unresolved.
Even though the order of flies (Diptera) is much older, true houseflies are believed to have evolved in the beginning of the Cenozoic era. They are thought to have originated in the southern Palearctic region, particularly the Middle East. Because of their close, commensal relationship with humans, they probably owe their worldwide dispersal to co-migration with humans.
The house fly is the most common of all domestic flies, accounting for about 91% of all flies in human habitations, and indeed one of the most widely distributed insects, found all over the world.
Relationship with humans
House flies are capable of carrying over 100 pathogens, such as those causing typhoid, cholera, salmonellosis, bacillary dysentery, tuberculosis, anthrax, ophthalmia, and parasitic worms. Some strains have become immune to the most common insecticides.
House flies feed on liquid or semiliquid substances beside solid material which has been softened by salivating or vomit. Because of their large intake of food, they deposit feces constantly, which is one of the factors that makes the insect a dangerous carrier of pathogens. Although they are domestic flies, usually confined to human habitations, they can fly for several miles from the breeding place. They are active only in daytime, and rest at night, e.g., at the corners of rooms, ceiling hangings, cellars, and barns, where they can survive the coldest winters by hibernation, and when spring arrives, adult flies are seen only a few days after the first thaw.
As a transmitter of disease
Mechanical transmission of organisms on its hairs, mouthparts, vomitus and feces:
- parasitic diseases: cysts of protozoa e.g. Entamoeba histolytica, Giardia lamblia and eggs of helminths, e.g., Ascaris lumbricoides, Trichuris trichiura, Hymenolepis nana, Enterobius vermicularis.
- bacterial diseases: typhoid, cholera, dysentery, pyogenic cocci, etc. House flies have been demonstrated to be vectors of Campylobacter and E. coli O157:H7 using PCR. House flies can be monitored for bacterial pathogens using filter paper spot cards and PCR 
- Viruses: enteroviruses: poliomyelitis, viral hepatitis (A & E)..etc.
Potential in waste management
The ability of housefly larvae to feed and develop in a wide range of decaying organic matter is important for recycling of nutrients in nature. Research suggests that this adaptation may be exploited to combat ever-increasing amounts of waste. Housefly larvae can be mass-reared in a controlled manner in animal manure, thus reducing the bulk of waste and minimizing environmental risks of its disposal. Harvested maggots may be used as feed for animal nutrition.
- Mandal, Fatik Baran (2015). Human Parasitology. PHI Learning Pvt. Ltd. p. 235. ISBN 9788120351158 – via Google Books.
- Larraín, Patricia; Salas, Claudio; Salas F (2008). "House fly (Musca domestica L.) (Diptera: Muscidae) development in different types of manure [Desarrollo de la Mosca Doméstica (Musca domestica L.) (Díptera: Muscidae) en Distintos Tipos de Estiércol]". Chilean Journal of Agricultural Research. 68 (2): 192–197. doi:10.4067/S0718-58392008000200009. ISSN 0718-5839.
- "Fly Mouthparts". bugs.bio.usyd.edu.au. Retrieved 2016-12-08.
- Stuart M. Bennett (2003). "Housefly".
- Sanchez-Arroyo, Hussein; Capinera, John L. (April 2017), Musca domestica Linnaeus, University of Florida, retrieved May 1, 2017
- Agarwal, S; Sohal, RS (December 1994). "DNA oxidative damage and life expectancy in houseflies". Proc. Natl. Acad. Sci. U.S.A. 91 (25): 12332–5. Bibcode:1994PNAS...9112332A. doi:10.1073/pnas.91.25.12332. PMC . PMID 7991627.
- Holmes, GE; Bernstein, C; Bernstein, H (September 1992). "Oxidative and other DNA damages as the basis of aging: a review". Mutation Research. 275 (3–6): 305–15. doi:10.1016/0921-8734(92)90034-M. PMID 1383772.
- Bernstein, Harris; Payne, Claire M.; Bernstein, Carol; Garewal, Harinder; Dvorak, Katerina (2008). "Cancer and Aging as Consequences of Un-repaired DNA Damage". In Kimura, Honoka; Suzuki, Aoi. New Research on DNA Damages. New York: Nova Science Publishers. pp. 1–47. ISBN 978-1-60456-581-2.
- Dübendorfer, A; Hediger, M; Burghardt, G; Bopp, D (2002). "Musca domestica, a window on the evolution of sex-determining mechanisms in insects". International Journal of Developmental Biology. 46 (1): 75–79. PMID 11902690.
- Wiegmann, BM; Yeates, DK; Thorne, JL; Kishino, H (December 2003). "Time flies, a new molecular time-scale for brachyceran fly evolution without a clock". Systematic Biology. 52 (6): 745–56. doi:10.1093/sysbio/52.6.745. PMID 14668115.
- Marquez, J. G.; Krafsur, E. S. (July 2002), "Gene Flow Among Geographically Diverse Housefly Populations (Musca domestica L.): A Worldwide Survey of Mitochondrial Diversity", J Hered (2002) 93 (4): 254–259, doi:10.1093/jhered/93.4.254
- Ostrolenk, M.; Welch H. (1942). "The house fly as a vector of food poisoning organisms in food producing establishments". American Journal of Public Health. 32 (5): 487–494. doi:10.2105/ajph.32.5.487.
- Levine, O.S.; Levine M.M. (1991). "House flies (Musca domestica) as mechanical vectors of shigellosis". Reviews of Infectious Diseases. 13 (4): 688–696. doi:10.1093/clinids/13.4.688. PMID 1925289.
- Förster, M.; Klimpel, S.; Sievert, K. (2009). "The house fly (Musca domestica) as a potential vector of metazoan parazites caught in a pig-pen in Germany". Veterinary Parasitology. 160 (1–2): 163–167. doi:10.1016/j.vetpar.2008.10.087. PMID 19081196.
- Georghiou, GP; Hawley, MK (1971). "Insecticide resistance resulting from sequential selection of houseflies in the field by organophosphorus compounds". Bulletin of the World Health Organization. 45 (1): 43–51. PMC . PMID 5316852.
- Keiding, J. (1975). "Problems of housefly (Musca domestica) control due to multiresistance to insecticides". Journal of Hygiene, Epidemiology, Microbiology, and Immunology. 19 (3): 340–355. PMID 52667.
- Nazni, W.A.; Luke, H.; Wan Rozita, W.M.; Abdullah, A.G.; Sadiyah, I.; Azahari, A.H.; Zamree, I.; Tan S.B.; Lee H.L. & Sofian A.M. (2005). "Determination of the flight range and dispersal of the house fly, Musca domestica (L.) using mark release recapture technique". Tropical Biomedicine. 22 (1): 53–61. PMID 16880754.
- A. L. Szalanski; C. B. Owens; T. Mckay; C. D. Steelman (2004). "Detection of Campylobacter and Escherichia coli O157:H7 from filth flies by polymerase chain reaction". Medical and Entomology. 18 (3): 241–246. doi:10.1111/j.0269-283X.2004.00502.x. PMID 15347391.
- Sheri M. Brazil; C. Dayton Steelman; Allen L. Szalanski (2007). "Detection of pathogen DNA from filth flies (Diptera: Muscidae) using filter paper spot cards". Journal of Agricultural and Urban Entomology. 24 (1): 13–18. doi:10.3954/1523-5475-24.1.13.
- Miller B. F.; Teotia J. S.; Thatcher T. O. (1974). "Digestion of poultry manure by Musca domestica". British Poultry Science. 15 (2): 231–1. doi:10.1080/00071667408416100. PMID 4447887.
- Cickova H.; Pastor B.; Kozanek M.; Martinez-Sanchez A.; Rojo S.; Takac P. (2012). "Biodegradation of pig manure by the housefly, Musca domestica: A viable ecological strategy for pig manure management". PLoS ONE. 7 (3): e32798. Bibcode:2012PLoSO...732798C. doi:10.1371/journal.pone.0032798. PMC . PMID 22431982.
- Zhu FX.; Wang WP.; Hong CL.; Feng MG.; Xue ZY.; Chen XY.; Yao YL.; Yu M. (2012). "Rapid production of maggots as feed supplement and organic fertilizer by the two-stage composting of pig manure". Bioresource Technology. 116: 485–491. doi:10.1016/j.biortech.2012.04.008. PMID 22541952.
- Hwangbo J.; Hong E. C.; Jang A.; Kang H. K.; Oh J. S.; Kim B. W.; Park B. S. (2009). "Utilization of house fly-maggots, a feed supplement in the production of broiler chickens". Journal of Environmental Biology. 30 (4): 609–614. PMID 20120505.
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- house fly on the UF / IFAS Featured Creatures Web site
- More about Lifespan of a fly, by D Nan
- Lifespan of a fly, by Kerri
- The House Fly and How to Suppress It, by L. O. Howard and F. C. Bishopp. U. S. Department of Agriculture Bulletin No. 1408, 1928, from Project Gutenberg. Also see:
- Stockbridge, Frank Parker (April 1912). "How To Get Rid Of Flies: The Way They "Swat" Them In Topeka And Order Out The Boy Scouts To Slaughter Them". The World's Work: A History of Our Time. XXIII: 692–701. Retrieved 2009-07-10.
- Page (editor), Walter Hines (June 1912). "How To Make A Flyless Town". The World's Work: A History of Our Time. XXIV: 176–179. Retrieved 2009-07-10.