Haematobia irritans

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Haematobia irritans
Horn flies.jpg
Haematobia irritans on horse
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Diptera
Family: Muscidae
Tribe: Stomoxyini
Genus: Haematobia
Species:
H. irritans
Binomial name
Haematobia irritans
Synonyms

Haematobia irritans, the horn fly, is a small fly (about half the size of a common housefly). It was first described by Carl Linnaeus in his 1758 10th edition of Systema Naturae. It is of the genus Haematobia which is the European genus of bloodsucking flies. Haematobia irritans is a native of Europe but has been introduced to North America and is considered a potentially dangerous livestock pest. [1]

Contents

Appearance

H. irritans is the smallest of the biting muscids, gray in color, approximately 316 in (4.0 mm) in length. Both the male and female have slender, black, piercing mouthparts which project forward from the bottom of the head. They often aggregate densely on cattle, each fly oriented with its head in the same direction as hair tips of that site on the host. Horn flies typically have eyes that are dark reddish brown. [1]

Egg laying, habitat and feeding

The horn fly lays eggs in fresh cow manure, and the female is known to lay her eggs in the feces before the cow has even completed defecation.

The larvae remain in fresh pats of the animal's dung and feed on both the resident bacterium and the compositions of the decomposition products of the resident bacterium.

The adult will find a suitable host and remains on it and others in the same herd for life, with the female only leaving to lay her eggs. Horn flies will also move around to different areas on the same animal to regulate their temperature and minimize their exposure to the wind. Both the male and the female subsist completely on blood, using their sharp mouthparts to pierce the animal's hide to suck it out.

Males typically feed around 20 times and females around 40 times daily, and when not feeding they tend to rest around the horn region of the host.

The gut microbiome has been investigated. Palavesam et al 2012 uses next generation sequencing to specify the symbiotic species helping H. irritans to digest bloodmeals. [2]

Stages of development

The horn fly undergoes complete metamorphosis, and has four major stages of development:

The first stage is the egg, which is laid in fresh feces, and hatches quickly. The resulting larval (maggot) stage, which consists of three larval instars (wingless), develops quickly and can last as little as four days. This is followed by the still immature pupa stage (also wingless) which lasts around six to eight days and finally the mature, winged adult stage.

Generational time may be as little as 10 days under ideal conditions, but under less favorable circumstances can average between 14 and 18 days.

Danger to livestock

The horn fly, as can be gleaned from its taxonomic designation Haematobia irritans, is an irritant to livestock. Beyond this, incessant biting is compounded by loss of blood, and results in such detrimental effects on host physiology as to include reduction in milk production, efficiency, and rate of gain. If the host is infested with a large number of flies, the resulting skin irritation and wounds may result in the drawing of a secondary infestation of myasis producing flies. There is some controversy over whether the horn fly is a disease vector, with at least one source asserting that the flies can be an intermediate host of Stephanofilaria stilesi , a parasite of cattle in North America.

Domestic animals affected

Primarily livestock (specifically cattle) are affected, but it is known to feed on horses, sheep and goats, albeit to a lesser extent.

Range

The horn fly is known as a strong flier, and upon emerging as adults they can fly up to 10 miles to find a host. However, most often a horn fly will not have to fly more than three miles to find a host.

Seasonality and locality

Found primarily in and around the states surrounding Kansas. Haematobia irritans is not native to the U.S. and originally came from Europe. It can live in any similarly climatized area, as evidenced by its most recent spread to Argentina and Uruguay. In the U.S., the active time of the horn fly is between April and October and, in a warm fall, even as late as mid-November. The flies are often most abundant from June through mid-July with a second population peak in mid-to-late August.

Management

Fly control tactics are moving away from dependence on pesticides, due to concern for the environment and pests developing resistance to insecticides. The first line of defense involves reducing the horn flies ability to reproduce. [3] Manure and wasted hay can be spread thinly for quick drying, or composted. Composting techniques must allow for the entire mass to reach temperatures that will kill insect eggs (e.g. the Berkley method). [4]

Rotating hens three days behind cattle is an effective method in reducing horn fly populations by scratching apart their habitat as they eat the horn fly larvae. The horn fly eggs take 1 to 2 days to hatch. [5]

Tree Swallow (14398630838).jpg

The tree swallow ( Tachycineta bicolor ) is also an effective predator of Haematobia irritans and can be attracted by building tree-swallow houses spaced approximately 100 feet apart. [6] Each adult tree swallow will consume about 2,000 insects per day during an average 45 day nesting period. The parents also catch and feed their brood (of 4-7 nestlings) about 6,000 insects per day during an average 20 days spent inside the nestbox. [7]

Parasitic wasps can reduce fly larvae by 90%. Put out enough wasps to inhibit what's left and put out more wasps every 30 days through summer. [8]

Dung beetles spend their lives in manure. Adults use liquid components as nourishment and lay eggs in the manure pat. The hatching larvae consume manure. Some species remove and bury balls of manure containing their eggs. An active population of dung beetles can bury or destroy 95% of horn fly eggs and larvae and about 90% of other cattle parasites that are passed in or depend on manure. Even if the fly eggs hatch in the manure balls, they can't get back up to the ground surface after being buried by the dung beetles. What's more, birds are attracted to manure containing dung beetles and tear the pats apart to eat them. This helps spread manure and disrupt fly-larvae development. A single manure pat without dung beetles can generate 60-80 adult horn flies. [3]

Insecticidal eartag Insecticidal eartag.jpg
Insecticidal eartag

Chemical methods have included pour-ons, backrubbers and face powder bags, with products such as Co-Ral which is available as dust for face/horn flies. Self-applicator methods such as dust bags and backrubbers are used mainly for range or pasture herds, and are placed so that the animal cannot avoid coming into contact with it, such as at a gate through which animals pass. More recently, control of the horn fly by using ear tags on cattle has been extremely successful. The ear tags are made of a PVC matrix impregnated with pyrethroid, and can be effective for between 16 and 24 weeks. Originally, the ear tags were developed and used against such pests as ticks and by 1983 50% of cattle had ear tags. long periods of such dosing resulted in the elimination of 95-99% of susceptible flies, but this strong selective pressure ended up resulting in the development of resistant strains of the flies. To combat this, the use of organophosphates and piperonyl butoxide as a synergist are now recommended to be alternated with pyrethroid to help slow resistance. In addition, methoprene in the form of sustained release bolus (a rounded mass of food or pharmaceutical preparation ready to swallow) inhibits the emergence of an adult insect from a pupal case or an insect larva from an egg for up to 7 months. New research (2011) has shown essential oil vapors from 16 species of eucalyptus to have toxicity against Haematobia irritans. [9]

Mutations and known variations

A white-eyed "albino" horn fly was discovered in a colony maintained at the Knipling-Bushland U.S. Livestock Insects Research Laboratory in Kerrville, Texas. This is apparently a spontaneous mutation, as tests including crosses were performed that determined the white-eye mutation was not sex-linked and the white-eyed flies actually have decreased amounts of eye pigment present within the head. This appears to be an inherited simple Mendelian autosomal recessive with complete penetrance. A colony of white-eyed horn flies was established from this single individual and has been maintained in the laboratory as visible genetic markers such as an eye color mutation in an economically important species like the horn fly may be useful for behavior and population dynamic studies, as well as release and recapture studies. No other differences from the wild-type flies were detected in the external characteristics of the mutant phenotype or in egg viability. However, white-eyed flies had significantly lower amounts of the pigment dihydroxyxanthommatin in their heads suggesting either the lack of xanthommatin production, or a failure of transport and storage within the head of the mutant phenotype.

Genomics

The insecticide susceptible Kerrville reference strain horn fly genome was assembled by the USDA-ARS Knipling-Bushland US Livestock Insects Research Laboratory in 2018. [10] The assembled size of the horn fly genome is 1.14 Gb which was close to previously published estimates using flow cytometry (1.2 Gb). This makes the horn fly genome larger than the genome sizes of the related Muscidae flies Musca domestica and Stomoxys calcitrans, which were reported as 1.0 Gb and 1.1 Gb. [10] [11] In addition to the nuclear genome of the Kerrville reference strain, the maternally inherited endosymbiont Wolbachia pipientiswIrr has also been assembled. [12]

Related Research Articles

<span class="mw-page-title-main">Forensic entomology</span> Application of insect and other arthropod biology to forensics

Forensic entomology is the scientific study of the colonization of a dead body by arthropods. This includes the study of insect types commonly associated with cadavers, their respective life cycles, their ecological presences in a given environment, as well as the changes in insect assemblage with the progression of decomposition. Insect succession patterns are identified based on the time a given species of insect spends in a given developmental stage, and how many generations have been produced since the insects introduction to a given food source. Insect development alongside environmental data such as temperature and vapor density, can be used to estimate the time since death, due to the fact that flying insects are attracted to a body immediately after death. The identification of postmortem interval to aid in death investigations is the primary scope of this scientific field. However, forensic entomology is not limited to homicides, it has also been used in cases of neglect and abuse, in toxicology contexts to detect the presence of drugs, and in dry shelf food contamination incidents. Equally, insect assemblages present on a body, can be used to approximate a given location, as certain insects may be unique to certain areas. Therefore, forensic entomology can be divided into three subfields: urban, stored-product and medico-legal/medico-criminal entomology.

<span class="mw-page-title-main">Fly</span> Order of insects

Flies are insects of the order Diptera, the name being derived from the Greek δι- di- "two", and πτερόν pteron "wing". Insects of this order use only a single pair of wings to fly, the hindwings having evolved into advanced mechanosensory organs known as halteres, which act as high-speed sensors of rotational movement and allow dipterans to perform advanced aerobatics. Diptera is a large order containing an estimated 1,000,000 species including horse-flies, crane flies, hoverflies, mosquitoes and others, although only about 125,000 species have been described.

<span class="mw-page-title-main">Tachinidae</span> Family of insects

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.

<span class="mw-page-title-main">Botfly</span> Parasitic insect

Botflies, also known as warble flies, heel flies, and gadflies, are a family of flies known as the Oestridae. Their larvae are internal parasites of mammals, some species growing in the host's flesh and others within the gut. Dermatobia hominis is the only species of botfly known to parasitize humans routinely, though other species of flies cause myiasis in humans.

<span class="mw-page-title-main">Phoridae</span> Family of flies

The Phoridae are a family of small, hump-backed flies resembling fruit flies. Phorid flies can often be identified by their escape habit of running rapidly across a surface rather than taking to the wing. This behaviour is a source of one of their alternate names, scuttle fly. Another vernacular name, coffin fly, refers to Conicera tibialis. About 4,000 species are known in 230 genera. The most well-known species is cosmopolitan Megaselia scalaris. At 0.4 mm in length, the world's smallest fly is the phorid Euryplatea nanaknihali.

<span class="mw-page-title-main">Stable fly</span> Species of fly

Stomoxys calcitrans is commonly called the stable fly, barn fly, biting house fly, dog fly, or power mower fly. Unlike most members of the family Muscidae, Stomoxys calcitrans and others of its genus suck blood from mammals. Now found worldwide, the species is considered to be of Eurasian origin.

<i>Hermetia illucens</i> Common and widespread fly of the family Stratiomyidae

Hermetia illucens, the black soldier fly, is a common and widespread fly of the family Stratiomyidae. Since the late 20th century, H. illucens has increasingly been gaining attention because of its usefulness for recycling organic waste and generating animal feed.

<i>Musca autumnalis</i> Species of fly

Musca autumnalis, the face fly or autumn housefly, is a pest of cattle and horses.

<i>Phormia regina</i> Species of fly

Phormia regina, the black blow fly, belongs to the blow fly family Calliphoridae and was first described by Johann Wilhelm Meigen.

<i>Scathophaga stercoraria</i> Species of fly

Scathophaga stercoraria, commonly known as the yellow dung fly or the golden dung fly, is one of the most familiar and abundant flies in many parts of the Northern Hemisphere. As its common name suggests, it is often found on the feces of large mammals, such as horses, cattle, sheep, deer, and wild boar, where it goes to breed. The distribution of S. stercoraria is likely influenced by human agriculture, especially in northern Europe and North America. The Scathophaga are integral in the animal kingdom due to their role in the natural decomposition of dung in fields. They are also very important in the scientific world due to their short life cycles and susceptibility to experimental manipulations; thus, they have contributed significant knowledge about animal behavior.

<span class="mw-page-title-main">Housefly</span> Species of insect

The housefly is a fly of the suborder Cyclorrhapha. It possibly originated in the Middle East, and spread around the world as a commensal of humans. It is the most common fly species found in houses. Adults are gray to black, with four dark, longitudinal lines on the thorax, slightly hairy bodies, and a single pair of membranous wings. They have red eyes, set farther apart in the slightly larger female.

<i>Chrysomya bezziana</i> Species of fly

Chrysomya bezziana, also known as the Old World screwworm fly or screwworm, is an obligate parasite of mammals. Obligate parasitic flies require a host to complete their development. Named to honor the Italian entomologist Mario Bezzi, this fly is widely distributed in Asia, tropical Africa, India, and Papua New Guinea. The adult can be identified as metallic green or blue with a yellow face and the larvae are smooth, lacking any obvious body processes except on the last segment.

<i>Hydrotaea</i> Genus of flies

Hydrotaea is a genus of insects in the housefly family, Muscidae. They occur in most regions of the world but are more populous in warmer climates. They are often found on feces in summer months, and are therefore generally found in close proximity to livestock. Among the 130 known species in this genus, one of the most commonly recognized is the dump fly.

<i>Muscina</i> Genus of flies

Muscina is a genus of flies that belongs to the family Muscidae, currently consisting of 27 species. They are worldwide in distribution and are frequently found in livestock facilities and outside restrooms. The most common species are M. stabulans, M. levida, and M. prolapsa. Muscina flies commonly breed in manure and defecate on food, which has been linked to the spread of some disease and illnesses. The occurrence of Muscina larvae on dead bodies has led to their regular use in forensic investigations, as they may be used to estimate the time of death. Research have shown the prevalence of certain species of Muscina flies as vectors of diseases such as poliomyelitis.

<i>Synthesiomyia nudiseta</i> Species of fly

Synthesiomyia nudiseta is one of the largest flies in the family Muscidae. The fly has a pair of forewings; the paired hind wings have been reduced to halteres that help with stability and movement during flight. Key characteristics of this species include plumose segmented aristae, well-developed calypters, and sternopleural bristles. Synthesiomyia nudiseta is a forensically important species because it is necrophilous and can therefore help determine the time of colonization for the post mortem interval with its known life cycle.

<i>Creophilus maxillosus</i> Species of beetle

Creophilus maxillosus, the hairy rove beetle, is a species of rove beetle.

<i>Musca vetustissima</i> Species of fly

Musca vetustissima, commonly known as the Australian bush fly, is a species of fly found in Australia. It is the specific fly that has given rise to the expression "Aussie salute".

The Australian Dung Beetle Project (1965–1985), conceived and led by Dr George Bornemissza of the Commonwealth Scientific and Industrial Research Organisation (CSIRO), was an international scientific research and biological control project with the primary goal to control the polluting effects of cattle dung.

<span class="mw-page-title-main">Parasitic flies of domestic animals</span> Overview of parasite-transmitting flies

Many species of flies of the two-winged type, Order Diptera, such as mosquitoes, horse-flies, blow-flies and warble-flies, cause direct parasitic disease to domestic animals, and transmit organisms that cause diseases. These infestations and infections cause distress to companion animals, and in livestock industry the financial costs of these diseases are high. These problems occur wherever domestic animals are reared. This article provides an overview of parasitic flies from a veterinary perspective, with emphasis on the disease-causing relationships between these flies and their host animals. The article is organized following the taxonomic hierarchy of these flies in the phylum Arthropoda, order Insecta. Families and genera of dipteran flies are emphasized rather than many individual species. Disease caused by the feeding activity of the flies is described here under parasitic disease. Disease caused by small pathogenic organisms that pass from the flies to domestic animals is described here under transmitted organisms; prominent examples are provided from the many species.

Mallophora ruficauda is a species of parasitic robber fly in the family Asilidae, endemic to South and Central America. Like other robber flies, M. ruficauda is known for its aggressive behavior and predation upon other insects, especially bees. M. ruficauda mimics a bumblebee to fool predators into thinking it has a painful sting and is not worth eating.

References

  1. 1 2 Gregor, F.; Rozkosny, R.; Bartak, M. & Vanhara, J. (2002). The Muscidae (Diptera) of Central Europe. Scientiarum Naturalium Universitatis Masarykianae Brunensis. Vol. 107. Masaryk: Masaryk University. p. 280.
  2. Thompson, Christopher R; Brogan, Rebecca S; Scheifele, Lisa Z; Rivers, David B (2013-11-01). "Bacterial Interactions with Necrophagous Flies". Annals of the Entomological Society of America . Entomological Society of America (OUP). 106 (6): 799–809. doi:10.1603/an12057. ISSN   1938-2901. S2CID   86054893.
  3. 1 2 "Outsmarting Flies On the Ranch"
  4. "The Rapid Composting Method"
  5. "Haematobia irritans irritans (Linnaeus) (Insecta: Diptera: Muscidae)"
  6. "How to Create and Manage Tree Swallow Nest Box Projects"
  7. "All About Tree Swallows on the Bluebird Trail".
  8. "7 ag stories you might have missed this week - Jan. 18, 2019"
  9. Juan, LW; Lucia, A; Zerba, EN; Harrand, L; Marco, M; Masuh, HM (2011). "Chemical composition and fumigant toxicity of the essential oils from 16 species of eucalyptus against Haematobia irritans (Diptera: Muscidae) adults". Journal of Economic Entomology. 104 (3): 1087–92. doi:10.1603/ec09431. hdl: 11336/81947 . PMID   21735933. S2CID   22890061.
  10. 1 2 Konganti K, Guerrero FD, Schilkey F, Ngam P, Jacobi JL, Umale PE; et al. (2018). "A Whole Genome Assembly of the Horn Fly, Haematobia irritans, and Prediction of Genes with Roles in Metabolism and Sex Determination". G3 (Bethesda). 8 (5): 1675–1686. doi:10.1534/g3.118.200154. PMC   5940159 . PMID   29602812.{{cite journal}}: CS1 maint: multiple names: authors list (link) Creative Commons by small.svg  This article incorporates text available under the CC BY 4.0 license.
  11. Picard CJ, Johnston JS, Tarone AM (2012). "Genome sizes of forensically relevant Diptera". J Med Entomol. 49 (1): 192–7. doi:10.1603/me11075. PMID   22308788. S2CID   46262649.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  12. Madhav M, Parry R, Morgan JAT, James P, Asgari S (2020). "Wolbachia Endosymbiont of the Horn Fly (Haematobia irritans irritans): a Supergroup A Strain with Multiple Horizontally Acquired Cytoplasmic Incompatibility Genes". Appl Environ Microbiol. 86 (6). Bibcode:2020ApEnM..86E2589M. doi:10.1128/AEM.02589-19. PMC   7054098 . PMID   31900308.{{cite journal}}: CS1 maint: multiple names: authors list (link)

Notes