Argas persicus

Last updated

Argas persicus
Argas persicus.jpg
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Subphylum: Chelicerata
Class: Arachnida
Order: Ixodida
Family: Argasidae
Genus: Argas
Species:
A. persicus
Binomial name
Argas persicus
(Oken, 1818)

Argas persicus, also known as fowl tick or poultry tick, is a small soft-bodied tick that is found primarily on domestic fowl such as chickens, ducks, and geese. It was first recorded by Lorenz Oken in 1818 in Mianeh, Persia, [1] [2] and named Rhynochoprion persicum.

Contents

Argas persicus appears yellowish-brown when starved and slatey-blue when engorged. They are found on an animal host, in cracks and crevices of buildings or in nests. [3] [4]

They are also carriers of the spirochete bacteria Borrelia anserina which causes avian spirochetosis, one of the most severe diseases affecting the poultry industry. [5]

In addition to domestic fowl, A. persicus may also feed on humans, although an immunity has been acquired by some individuals. [6] [7]

Distribution

The fowl tick is distributed worldwide but does tend to prefer a warmer climate. [8] The lower United States especially sees a large distribution of this soft bodied tick due to the warm climate. [9]

Life Cycle

Argasid (soft) ticks have a multihost life cycle meaning it has two or more nymphal stages that each require a blood meal. [10]

Mating and the laying of eggs occurs off the host and in sheltered areas such as bird nests. Six-legged larvae hatch from the eggs in the chosen sheltered area. Once a suitable host is found in the vicinity, they begin to feed for a few hours to a few days. The larvae finish feeding and leaves the host for an area of shelter. The larvae then molt to become the first nymph stage. The first nymphs stage then move onto the second host to feed. This second host may be the same individual as the first and is likely the same species. The first stage of nymphs transforms to the next nymph stage when it leaves the host and molts once more. These nymph stages can reach up to seven stages. After the last nymph stage, it leaves the host to molt into an adult. The adults can continue to feed on the host feeding quickly and detaching from the host after each blood meal. Females often lay eggs after each meal when off the host. [11]

Pathogen Transmission

A. persicus is a natural reservoir for B. anserina as it helps these spirochetes survive longer. [12] West Nile virus was also found to be able to infect the tick when feeding on an infected membrane. This was tested using artificial inoculation. [13] If the pathogen infects humans due to A. persicus, it would likely be as an incidental host but humans may be fed upon by any of the stages. [14]

Disease and Symptoms

Avian Spirochetosis

This disease is sepsis by B. anserina being transmitted in A. persicus saliva. The spirochete can be seen in blood samples taken from infected birds. [15] [16] Young birds appear to be especially susceptible to the larvae of A. persicus due to not having been exposed to it before. Although domestic birds do not fully develop immunity against the paralysis inducing toxins produced, a weak protective mechanism may result from having been infected. [17]

Symptoms of avian spirochetosis include drop in egg production, depression, polydipsia (increased thirst), drowsiness, anorexia, loss of appetite, green diarrhea, ruffled feathers, pale combs, weight loss, paralysis of the legs and wings (flaccid paralysis), and abrupt death. Before death, the bird tends to become recumbent or begins to lie down stretched out. This is especially true when heavily infested with the larval stage of A. persicus. [18] [19]

Fowl Tick Infection and Tick Paralysis

Tick paralysis is included in avian spirochetosis and appears in the same fashion. The flaccid paralysis ascends throughout the body. Incoordination first occurs followed by paralysis of the hind limbs, forelimbs, and then leads to respiratory distress and failure. Death then follows. Blood loss during infection could occur as well and result in clinical anemia. [20]

Treatment

Controlling the larvae is important as it acts as a vector for B. anserina. Repeated treatments with malathion spray helps to reduce the ticks and helps the birds recover. Penicillin injections appear to have no effect in treatment of the bacteria. [21] The elimination of tick larvae is key to reversing the effects of avian spirochetosis. Hydration is also extremely important as death most often results due to dehydration from prolonged paralysis. [22]

Related Research Articles

<span class="mw-page-title-main">Tick</span> Order of arachnids in the arthropod phylum

Ticks are parasitic arachnids that are part of the mite superorder Parasitiformes. Adult ticks are approximately 3 to 5 mm in length depending on age, sex, species, and "fullness". Ticks are external parasites, living by feeding on the blood of mammals, birds, and sometimes reptiles and amphibians. The timing of the origin of ticks is uncertain, though the oldest known tick fossils are from the Cretaceous period, around 100 million years old. Ticks are widely distributed around the world, especially in warm, humid climates.

<span class="mw-page-title-main">Ixodidae</span> Family of ticks

The Ixodidae are the family of hard ticks or scale ticks, one of the three families of ticks, consisting of over 700 species. They are known as 'hard ticks' because they have a scutum or hard shield, which the other major family of ticks, the 'soft ticks' (Argasidae), lack. They are ectoparasites of a wide range of host species, and some are vectors of pathogens that can cause human disease.

<span class="mw-page-title-main">Lyme disease</span> Infectious disease caused by Borrelia bacteria, spread by ticks

Lyme disease, also known as Lyme borreliosis, is a vector-borne disease caused by Borrelia bacteria, which are spread by ticks in the genus Ixodes. The most common sign of infection is an expanding red rash, known as erythema migrans (EM), which appears at the site of the tick bite about a week afterwards. The rash is typically neither itchy nor painful. Approximately 70–80% of infected people develop a rash. Early diagnosis can be difficult. Other early symptoms may include fever, headaches and tiredness. If untreated, symptoms may include loss of the ability to move one or both sides of the face, joint pains, severe headaches with neck stiffness or heart palpitations. Months to years later, repeated episodes of joint pain and swelling may occur. Occasionally, shooting pains or tingling in the arms and legs may develop. Despite appropriate treatment, about 10 to 20% of those affected develop joint pains, memory problems, and tiredness for at least six months.

<i>Borrelia burgdorferi</i> Species of bacteria

Borrelia burgdorferi is a bacterial species of the spirochete class in the genus Borrelia, and is one of the causative agents of Lyme disease in humans. Along with a few similar genospecies, some of which also cause Lyme disease, it makes up the species complex of Borrelia burgdorferi sensu lato. The complex currently comprises 20 accepted and 3 proposed genospecies. B. burgdorferi sensu stricto exists in North America and Eurasia and until 2016 was the only known cause of Lyme disease in North America. Borrelia species are Gram-negative.

<i>Ixodes holocyclus</i> Species of tick

Ixodes holocyclus, commonly known as the Australian paralysis tick, is one of about 75 species in the Australian tick fauna and is considered the most medically important. It can cause paralysis by injecting neurotoxins into its host. It is usually found in a 20-kilometre wide band following the eastern coastline of Australia. Within this range Ixodes holocyclus is the tick most frequently encountered by humans and their pets. As this area also contains Australia's most densely populated regions, bites on people, pets and livestock are relatively common.

<i>Borrelia</i> Genus of bacteria

Borrelia is a genus of bacteria of the spirochete phylum. Several species cause Lyme disease, also called Lyme borreliosis, a zoonotic, vector-borne disease transmitted by ticks. Other species of Borrelia cause relapsing fever, and are transmitted by ticks or lice, depending on the species of bacteria. A few Borrelia species as Candidatus Borrelia mahuryensis harbor intermediate genetic features between Lyme disease and relapsing fever Borrelia. The genus is named after French biologist Amédée Borrel (1867–1936), who first documented the distinction between a species of Borrelia, B. anserina, and the other known type of spirochete at the time, Treponema pallidum. This bacterium must be viewed using dark-field microscopy, which make the cells appear white against a dark background. Borrelia species are grown in Barbour-Stoenner-Kelly medium. Of 52 known species of Borrelia, 20 are members of the Lyme disease group, 29 belong to the relapsing fever group, and two are members of a genetically distinct third group typically found in reptiles. A proposal has been made to split the Lyme disease group based on genetic diversity and move them to their own genus, Borelliella, but this change is not widely accepted. This bacterium uses hard and soft ticks and lice as vectors. Testing for the presence of the bacteria in a human includes two-tiered serological testing, including immunoassays and immunoblotting.

Borrelia anserina is a helical spirochete bacterium with dimensions around 8-20/0,2-0,3 μm and with five to eight spirals. Their mobility is very high. B. anserina can be colored with the May Grunwald-Giemsa method.

<i>Ixodes scapularis</i> Species of tick

Ixodes scapularis is commonly known as the deer tick or black-legged tick, and in some parts of the US as the bear tick. It was also named Ixodes dammini until it was shown to be the same species in 1993. It is a hard-bodied tick found in the eastern and northern Midwest of the United States as well as in southeastern Canada. It is a vector for several diseases of animals, including humans and is known as the deer tick owing to its habit of parasitizing the white-tailed deer. It is also known to parasitize mice, lizards, migratory birds, etc. especially while the tick is in the larval or nymphal stage.

<i>Ixodes ricinus</i> Species of tick

Ixodes ricinus, the castor bean tick, is a chiefly European species of hard-bodied tick. It may reach a length of 11 mm (0.43 in) when engorged with a blood meal, and can transmit both bacterial and viral pathogens such as the causative agents of Lyme disease and tick-borne encephalitis.

<i>Amblyomma americanum</i> Species of tick

Amblyomma americanum, also known as the lone star tick, the northeastern water tick, or the turkey tick, is a type of tick indigenous to much of the eastern United States and Mexico, that bites painlessly and commonly goes unnoticed, remaining attached to its host for as long as seven days until it is fully engorged with blood. It is a member of the phylum Arthropoda, class Arachnida. The adult lone star tick is sexually dimorphic, named for a silvery-white, star-shaped spot or "lone star" present near the center of the posterior portion of the adult female shield (scutum); adult males conversely have varied white streaks or spots around the margins of their shields.

<i>Ixodes pacificus</i> Species of arachnid

Ixodes pacificus, the western black-legged tick, is a species of parasitic tick found on the western coast of North America. I. pacificus is a member of the family Ixodidae. It is the principal vector of Lyme disease in that region. I. pacificus typically feeds on lizards and small mammals therefore its rate of transmission of Lyme disease to humans is around 1% of adults. It is an ectoparasite that attaches itself to the outside of its host and feeds on the host's blood. It can have a heteroxenous lifestyle or monoxenous life cycle depending on how many hosts it feeds on in each cycle. I. pacificus has a four stage life cycle that takes around 3 years to complete. These stages include egg, larva, nymph, and adult. They prefer dense woodland habitats or areas of brush and tall grass.

<i>Ornithodoros hermsi</i> Species of tick

Ornithodoros hermsi is a species of soft tick. It can be infected with Borrelia hermsii.

<i>Ornithodoros moubata</i> Species of tick

Ornithodoros moubata, commonly known as the African hut tampan or the eyeless tampan, is a species of tick in the family Argasidae. It is an ectoparasite and vector of relapsing fever in humans, and African swine fever in pigs.

Brachyspira pilosicoli is a gram-negative, anaerobic, host-associated spirochete that colonizes the intestinal tract of animals and humans. It appears as a characteristic "false brush border" due to its end-on attachment to enterocytes of the colon where it interferes with intestinal absorption. B. pilosicoli is unique from other Brachyspira species because it colonizes a variety of domestic animals including pigs, chickens, dogs, wild birds, rodents, and humans. It is the causative agent of intestinal spirochetosis in pigs, chickens and humans. In particular, B. pilosicoli has been described as an important colonic pathogen of pigs and chickens, causing colitis and diarrhea resulting in depressed rates of growth and impaired production on farms where infections with B. pilosicoli may be endemic. Bacterial attachment disrupts the colonic enterocytes and associated villi, causing the symptoms characteristic of intestinal spirochetosis. Additionally, B. pilosicoli is associated with clinical disease in human infections where it has implications for public health.

<span class="mw-page-title-main">Ticks of domestic animals</span>

Ticks of domestic animals directly cause poor health and loss of production to their hosts. Ticks also transmit numerous kinds of viruses, bacteria, and protozoa between domestic animals. These microbes cause diseases which can be severely debilitating or fatal to domestic animals, and may also affect humans. Ticks are especially important to domestic animals in tropical and subtropical countries, where the warm climate enables many species to flourish. Also, the large populations of wild animals in warm countries provide a reservoir of ticks and infective microbes that spread to domestic animals. Farmers of livestock animals use many methods to control ticks, and related treatments are used to reduce infestation of companion animals.

<span class="mw-page-title-main">Weather and climate effects on Lyme disease exposure</span>

Lyme disease is spread to humans through the bite of infected ticks. The tick population is affected by weather and climate. Many factors determine tick population densities as well as diseased population densities of ticks so that no single factor can determine likelihood of exposure to tick-borne disease. Overall climate and primary host population determine the localities where ticks will thrive. However, studies have been conducted which correlate tick population to climate change and their behavior to weather patterns. Ticks are parasites which carry a myriad of infectious diseases that depend on the species of tick. Overall climate is more determinate of tick population and daily weather has a subtle effect on the spread of tick-borne disease. Being mindful of daily weather patterns and vigilantly avoiding exposure to ticks reduces human exposure to Lyme disease.

<span class="mw-page-title-main">Mites of domestic animals</span> Type of parasite of domestic animals

Mites that infest and parasitize domestic animals cause disease and loss of production. Mites are small invertebrates, most of which are free living but some are parasitic. Mites are similar to ticks and both comprise the order Acari in the phylum Arthropoda. Mites are highly varied and their classification is complex; a simple grouping is used in this introductory article. Vernacular terms to describe diseases caused by mites include scab, mange, and scabies. Mites and ticks have substantially different biology from, and are classed separately from, insects. Mites of domestic animals cause important types of skin disease, and some mites infest other organs. Diagnosis of mite infestations can be difficult because of the small size of most mites, but understanding how mites are adapted to feed within the structure of the skin is useful.

<span class="mw-page-title-main">Mites of livestock</span> Small crawling animals related to ticks and spiders

Mites are small crawling animals related to ticks and spiders. Most mites are free-living and harmless. Other mites are parasitic, and those that infest livestock animals cause many diseases that are widespread, reduce production and profit for farmers, and are expensive to control.

<i>Ornithodoros savignyi</i> Species of tick

Ornithodoros savignyi, known as sand tampan, African eyed tampan or Kalahari sand tampan, is one of some 37 species in the genus Ornithodoros and is a soft tick with a leathery, mammillated integument, causing paralysis and tampan toxicosis, two unrelated conditions. The sand tampan is an ectoparasite on humans, their livestock and wild animals, including birds and bats. Occurring in semi-desert areas of Africa, Saudi Arabia and other parts of the Persian Gulf, India, Sri Lanka and into Asia, it is able to survive for lengthy periods without feeding, spending most of its life burrowed under sand or loose soil, often in wait for animals that rest or sleep under trees or in the lee of rocks, but also in places where people or their animals congregate such as marketplaces, places of worship, cattle kraals and village squares. The timing of its activity is geared to coincide with that of potential hosts, but hot sunny conditions are usually avoided. Because of its habit of feeding and dropping from its host, adult dispersal is limited, whereas larvae may remain attached to their hosts for several days. During its life cycle it will feed on multiple hosts between moults.

<span class="mw-page-title-main">Houghton Poultry Research Station</span> Agricultural research institute in Houghton, Cambridgeshire

The Houghton Poultry Research Station was a poultry disease research station in northern Cambridgeshire.

References

  1. L. S. Fortescue (1924). "The Western Elburz and Persian Azerbaijan". The Geographical Journal . 63 (4): 301–315. doi:10.2307/1781408. JSTOR   1781408.
  2. "Argas Persicus - Fowl Tick (Invertebrate Species Summary)." WildPro. Ed. Debra Bourne. East Midland Zoological Society, Dec. 2013. Web. 15 Apr. 2017.
  3. "Argas Persicus - Fowl Tick (Invertebrate Species Summary)." WildPro. Ed. Debra Bourne. East Midland Zoological Society, Dec. 2013. Web. 15 Apr. 2017.
  4. "DPDx - Laboratory Identification of Parasitic Diseases of Public Health Concern." Centers for Disease Control and Prevention. Centers for Disease Control and Prevention, 03 May 2016. Web. 15 Apr. 2017.
  5. Lisbôa, R. S., R. C. Teixeira, C. P. Rangel, H. A. Santos, C. L. Massard, and A. H. Fonseca. "Avian Spirochetosis in Chickens following Experimental Transmission of Borrelia Anserina by Argas (Persicargas) Miniatus." Avian Diseases. U.S. National Library of Medicine, June 2009. Web. 15 Apr. 2017.
  6. L. S. Fortescue (1924). "The Western Elburz and Persian Azerbaijan". The Geographical Journal. 63 (4): 301–315. JSTOR   1781408.
  7. William Trager (1940). "A note on the problem of acquired immunity to argasid ticks". Journal of Parasitology. 26 (1): 71–74. JSTOR   3272265.
  8. Lisbôa, R. S., R. C. Teixeira, C. P. Rangel, H. A. Santos, C. L. Massard, and A. H. Fonseca. "Avian Spirochetosis in Chickens following Experimental Transmission of Borrelia Anserina by Argas (Persicargas) Miniatus." Avian Diseases. U.S. National Library of Medicine, June 2009. Web. 15 Apr. 2017.
  9. Rosenstein, M. "Paralysis in Chickens Caused by Larvae of the Poultry Tick, Argas Persicus." Avian Diseases 20.2 (1976): 407-09. JSTOR. American Association of Avian Pathologists, Inc. Web. 15 Apr. 2017.
  10. "DPDx - Laboratory Identification of Parasitic Diseases of Public Health Concern." Centers for Disease Control and Prevention. Centers for Disease Control and Prevention, 03 May 2016. Web. 15 Apr. 2017.
  11. "DPDx - Laboratory Identification of Parasitic Diseases of Public Health Concern." Centers for Disease Control and Prevention. Centers for Disease Control and Prevention, 03 May 2016. Web. 15 Apr. 2017.
  12. Lisbôa, R. S., R. C. Teixeira, C. P. Rangel, H. A. Santos, C. L. Massard, and A. H. Fonseca. "Avian Spirochetosis in Chickens following Experimental Transmission of Borrelia Anserina by Argas (Persicargas) Miniatus." Avian Diseases. U.S. National Library of Medicine, June 2009. Web. 15 Apr. 2017.
  13. "Argas Persicus - Fowl Tick (Invertebrate Species Summary)." WildPro. Ed. Debra Bourne. East Midland Zoological Society, Dec. 2013. Web. 15 Apr. 2017.
  14. "DPDx - Laboratory Identification of Parasitic Diseases of Public Health Concern." Centers for Disease Control and Prevention. Centers for Disease Control and Prevention, 03 May 2016. Web. 15 Apr. 2017.
  15. "Argas Persicus - Fowl Tick (Invertebrate Species Summary)." WildPro. Ed. Debra Bourne. East Midland Zoological Society, Dec. 2013. Web. 15 Apr. 2017.
  16. Lisbôa, R. S., R. C. Teixeira, C. P. Rangel, H. A. Santos, C. L. Massard, and A. H. Fonseca. "Avian Spirochetosis in Chickens following Experimental Transmission of Borrelia Anserina by Argas (Persicargas) Miniatus." Avian Diseases. U.S. National Library of Medicine, June 2009. Web. 15 Apr. 2017.
  17. Rosenstein, M. "Paralysis in Chickens Caused by Larvae of the Poultry Tick, Argas Persicus." Avian Diseases 20.2 (1976): 407-09. JSTOR. American Association of Avian Pathologists, Inc. Web. 15 Apr. 2017.
  18. Lisbôa, R. S., R. C. Teixeira, C. P. Rangel, H. A. Santos, C. L. Massard, and A. H. Fonseca. "Avian Spirochetosis in Chickens following Experimental Transmission of Borrelia Anserina by Argas (Persicargas) Miniatus." Avian Diseases. U.S. National Library of Medicine, June 2009. Web. 15 Apr. 2017.
  19. Rosenstein, M. "Paralysis in Chickens Caused by Larvae of the Poultry Tick, Argas Persicus." Avian Diseases 20.2 (1976): 407-09. JSTOR. American Association of Avian Pathologists, Inc. Web. 15 Apr. 2017.
  20. "Argas Persicus - Fowl Tick (Invertebrate Species Summary)." WildPro. Ed. Debra Bourne. East Midland Zoological Society, Dec. 2013. Web. 15 Apr. 2017.
  21. Dickie, Charles W., and James Barrera. "A Study of the Carrier State of Avian Spirochetosis in the Chicken." Avian Diseases 8.2 (1964): 191-95. JSTOR. American Association of Avian Pathologists. Web. 15 Apr. 2017.
  22. Rosenstein, M. "Paralysis in Chickens Caused by Larvae of the Poultry Tick, Argas Persicus." Avian Diseases 20.2 (1976): 407-09. JSTOR. American Association of Avian Pathologists, Inc. Web. 15 Apr. 2017.

Further reading

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.