The BioFiles - Bill Hubick

Black-legged Tick (Ixodes scapularis)

Source: Wikipedia

Ixodes scapularis
Adult female deer tick
Scientific classification Edit this classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Subphylum: Chelicerata
Class: Arachnida
Order: Ixodida
Family: Ixodidae
Genus: Ixodes
Species:
I. scapularis
Binomial name
Ixodes scapularis
Say, 1821
Synonyms[1]
  • Ixodes dammini Spielman et al., 1979
  • Ixodes fuscous Say, 1821
  • Ixodes fuscus Neumann, 1911
  • Ixodes ozarkus Cooley, 1944
  • Ixodes reduvius Neumann, 1899
  • Ixodes ricinus subsp. scapularis Nuttall & Warburton, 1911
  • Ixodes ricinus var. scapularis Nuttall & Warburton, 1911
  • Ixodes (Ixodes) scapularis Neumann, 1911

Ixodes scapularis is commonly known as the deer tick or black-legged tick (although some people reserve the latter term for Ixodes pacificus, which is found on the west coast of the US), and in some parts of the US as the bear tick.[2] It was also named Ixodes dammini until it was shown to be the same species in 1993.[3] 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 (Lyme disease, babesiosis, anaplasmosis, Powassan virus disease, etc.) and is known as the deer tick owing to its habit of parasitizing the white-tailed deer. It is also known to parasitize mice,[4] lizards,[5] migratory birds,[6] etc. especially while the tick is in the larval or nymphal stage.

Deer tick

Description

[edit]

As a nymph and adult, Ixodes scapularis has eight legs, while larvae have six.[7] Unlike ticks from other genera,[8] deer ticks do not have eyes.[3][8] The scutum is dark, inornate (plain), and, in unfed females, contrasts with the exposed orange or red remainder of the idiosoma.[3] There are no festoons.[3][9] Ixodes ticks have an anal groove that resembles a horseshoe[9] on their underside anterior to the anal pore.[8][10] The palps of male deer ticks, part of the mouthparts or capitulum, are shorter than those of the female.[7][11]: 5  Adult female deer ticks are approximately 3 to 4 mm long,[10] and may engorge while feeding,[7] while adult males are 2 to 3 mm long[10] and cannot engorge due to the rigidity of their scutum, which covers the entire male body.[7]

Behavior

[edit]

Ixodes scapularis has a 2-year life cycle, during which time it passes through three stages: larva, nymph, and adult. The tick must take a blood meal at each stage before maturing to the next. Deer tick females latch onto a host and drink its blood for 4–5 days. Deer are the preferred host of the adult deer tick, but it is also known to feed on small rodents.[12] After she is engorged, the tick drops off and overwinters in the leaf litter of the forest floor. The following spring, the female lays several hundred to a few thousand eggs in clusters.[13] Transtadial (between tick stages) passage of Borrelia burgdorferi is common. Vertical passage (from mother to egg) of Borrelia is uncommon.[citation needed]

Like other ticks, I. scapularis is hardy. It can be active after a hard frost, as daytime temperatures can warm it enough to keep it actively searching for a host. In the spring, it can be one of the first invertebrates to become active. Deer ticks can be quite numerous and seemingly gregarious.[citation needed]

Deer tick life cycle

As disease vector

[edit]
Deer tick
Deer Ticks
3D rendering of a male and female deer tick

Ixodes scapularis is the main vector of Lyme disease in North America.[14] The CDC reported over 30,000 new cases of the disease in 2016 alone, the majority of which were contracted in the summer months, which is when ticks are most likely to bite humans.[15] While adult deer ticks are more likely to carry and transmit Borrelia burgdorferi, it is more common for the hard-to-spot nymphal stage to infect humans.[16]

It can also transmit other Borrelia species, including Borrelia miyamotoi.[17] Ticks that transmit B. burgdorferi to humans can also carry and transmit several other parasites, such as Babesia microti and Anaplasma phagocytophilum, which cause the diseases babesiosis and human granulocytic anaplasmosis (HGA), respectively.[18] Among early Lyme disease patients, depending on their location, 2%–12% will also have HGA and 2%–40% will have babesiosis.[19]

Engorged deer tick

Co-infections complicate Lyme symptoms, especially diagnosis and treatment. It is possible for a tick to carry and transmit one of the co-infections and not Borrelia, making diagnosis difficult and often elusive. The Centers for Disease Control's emerging infectious diseases department did a study in rural New Jersey of 100 ticks, and found 55% of the ticks were infected with at least one of the pathogens.[20]

Deer, the preferred mammalian hosts of adult I. scapularis, cannot transmit Borrelia spirochaetes to ticks. Ticks acquire Lyme disease microbes by feeding on infected mice and other small rodents as nymphs or larvae.[12]

One of the keys of the success of I. scapularis as a Borrelia vector relies on its ability to limit the proliferation of the spirochaete. This is due to the activity of domesticated amidase effector (dae) genes. Dae genes are a family of horizontally acquired genes related to type VI secretion amidase effector (tae) genes in certain bacteria which encode toxins honed to mediate interbacterial antagonism. Once transferred to eukaryotes tae genes confer novel antibacterial capabilities;[21] this provides a selective advantage to the tick and to other eukaryotes also: tae genes have been transferred from bacteria to eukaryotes at least in six independent events. In particular, I. scapularis have inherited the dae 2 family from a common ancestor between ticks and mites.[21] The product of dae2 expression has been shown to degrade bacterial peptidoglycan of different species and particularly from B. burgdorferi, but does not limit initial acquisition of the bacterium by the tick. Dae2 contributes to the innate ability of I. scapularis to control B. burgdorferi levels after its acquisition. This has potential ramifications for Lyme disease transmission, as spirochaete load in the tick can influence transmission efficiency.[21][22]

A recent study has identified the alpha-gal sugar in the tick, and they have suggested that it may also be involved in the onset of red meat allergy (Alpha-Gal Syndrome or Mammalian Meat Allergy, MMA).[23]

Genome sequencing

[edit]
Genomic information
NCBI genome ID523
Ploidydiploid
Genome size1,765.38 Mb
Number of chromosomes15 pairs
Year of completion2008

The genome of I. scapularis has been sequenced.[24]

See also

[edit]

References

[edit]
  1. ^ "Ixodes scapularis Say, 1821". Global Biodiversity Information Facility. Retrieved 11 April 2024.
  2. ^ Drummond, Roger (2004). Ticks and What You Can Do about Them (3rd ed.). Berkeley, California: Wilderness Press. p. 23. ISBN 978-0-89997-353-1.
  3. ^ a b c d Patnaude, Michael R.; Mather, Thomas N. (December 2014) [Originally published July 2000]. Rhodes, Elena (ed.). "Deer tick, Ixodes scapularis Say". Featured Creatures. Photographs by Michael R. Patnaude, web design by Kay Weigel. University of Florida Entomology & Nematology, Institute of Food and Agricultural Sciences. Retrieved 11 April 2024.
  4. ^ Mannelli, A; Kitron, U; Jones, C. J.; Slajchert, T. L. (1994). "Influence of season and habitat on Ixodes scapularis infestation on white-footed mice in northwestern Illinois". The Journal of Parasitology. 80 (6): 1038–42. doi:10.2307/3283457. JSTOR 3283457. PMID 7799148.
  5. ^ Levine, J. F.; Apperson, C. S.; Howard, P; Washburn, M; Braswell, A. L. (1997). "Lizards as hosts for immature Ixodes scapularis (Acari: Ixodidae) in North Carolina". Journal of Medical Entomology. 34 (6): 594–8. doi:10.1093/jmedent/34.6.594. PMID 9439111.
  6. ^ Ogden NH, Lindsay LR, Hanincová K, Barker IK, Bigras-Poulin M, Charron DF, Heagy A, Francis CM, O'Callaghan CJ, Schwartz I, Thompson RA (2008). "Role of migratory birds in introduction and range expansion of Ixodes scapularis ticks and of Borrelia burgdorferi and Anaplasma phagocytophilum in Canada". Applied and Environmental Microbiology. 74 (6): 1780–90. Bibcode:2008ApEnM..74.1780O. doi:10.1128/AEM.01982-07. PMC 2268299. PMID 18245258.
  7. ^ a b c d Thivierge, Karine; Cecan, Alexandra; Saint-Pierre, Dominique; Bertrand, Vicky; Germain, Geneviève (2024). "Detailed description of the Ixodes scapularis, or black-legged tick or deer tick". Institut national de santé publique du Québec. Government du Québec. Retrieved 11 April 2024.
  8. ^ a b c Thivierge, Karine; Cecan, Alexandra; Saint-Pierre, Dominique; Bertrand, Vicky; Germain, Geneviève (2024). "Other tick species found in Québec". Institut national de santé publique du Québec. Government du Québec. Retrieved 11 April 2024.
  9. ^ a b Thevanayagam, Sharavanan (2012). Liere, Heidi; Marino, John; OConnor, Barry; Mulcrone, Renee (eds.). "Ixodes scapularis". Animal Diversity Web. Retrieved 11 April 2024.
  10. ^ a b c Houseman, Richard M. (August 2013). "Ticks and Tick-borne Diseases". MU Extension. Curators of the University of Missouri. Retrieved 11 April 2024.
  11. ^ Hill, Catherine A.; MacDonald, John F. (August 2013). "THE BIOLOGY AND MEDICAL IMPORTANCE OF TICKS IN INDIANA" (PDF). Purdue Extension Public Health Department of Entomology. Publication ID E-243-W. Retrieved 11 April 2024.
  12. ^ a b "Westport Weston Health District". 2004. Archived from the original on 2013-09-29. Retrieved 2013-09-26.
  13. ^ Suzuki, David; Grady, Wayne (2004). Tree: A Life Story. Vancouver: Greystone Books. pp. 110. ISBN 978-1-55365-126-0.
  14. ^ Brownstein, John S.; Holford, Theodore R.; Fish, Durland (2005). "Effect of Climate Change on Lyme Disease Risk in North America". EcoHealth. 2 (1): 38–46. doi:10.1007/s10393-004-0139-x. PMC 2582486. PMID 19008966.
  15. ^ "Lyme disease graphs | Lyme Disease | CDC". www.cdc.gov. 2017-11-06. Retrieved 2018-05-18.
  16. ^ "Transmission of Lyme disease | CDC". 29 January 2020.
  17. ^ McNeil, Donald (19 September 2011). "New Tick-Borne Disease Is Discovered". The New York Times. pp. D6. Retrieved 20 September 2011.
  18. ^ Steere AC (July 2001). "Lyme disease". New England Journal of Medicine. 345 (2): 115–25. doi:10.1056/NEJM200107123450207. PMID 11450660.
  19. ^ G. P. Wormser (June 2006). "Clinical practice. Early Lyme disease". New England Journal of Medicine. 354 (26): 2794–801. doi:10.1056/NEJMcp061181. PMID 16807416.
  20. ^ Varde S, Beckley J, Schwartz I (1998). "Prevalence of tick-borne pathogens in Ixodes scapularis in a rural New Jersey County". Emerging Infectious Diseases. 4 (1): 97–99. doi:10.3201/eid0401.980113. PMC 2627663. PMID 9452402.
  21. ^ a b c Seemay Chou; Matthew D. Daugherty; S. Brook Peterson; Jacob Biboy; Youyun Yang; Brandon L. Jutras; Lillian K. Fritz-Laylin; Michael A. Ferrin; Brittany N. Harding; Christine Jacobs-Wagner; X. Frank Yang; Waldemar Vollmer; Harmit S. Malik; Joseph D. Mougous (2014). "Transferred interbacterial antagonism genes augment eukaryotic innate immune function". Nature. 518 (7537): 98–101. doi:10.1038/nature13965. PMC 4713192. PMID 25470067.
  22. ^ Erin Garcia de Jesus (10 December 2020). "How some ticks protect themselves from deadly bacteria on human skin". ScienceNews.
  23. ^ Crispell, Gary; Commins, Scott P.; Archer-Hartman, Stephanie A.; Choudhary, Shailesh; Dharmarajan, Guha; Azadi, Parastoo; Karim, Shahid (17 May 2019). "Discovery of Alpha-Gal-Containing Antigens in North American Tick Species Believed to Induce Red Meat Allergy". Frontiers in Immunology. 10: 1056. doi:10.3389/fimmu.2019.01056. PMC 6533943. PMID 31156631.
  24. ^ Ixodes scapularis genome sequence at VectorBase
[edit]