Biology:Triatominae

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Short description: Subfamily of true bugs

Triatominae
Temporal range: Cenomanian–Recent
Pgeniculatus2.jpg
Scientific classification e
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Hemiptera
Suborder: Heteroptera
Family: Reduviidae
Subfamily: Triatominae
Jeannel, 1919
Tribes

The members of the Triatominae /tr.əˈtɒmɪn/, a subfamily of the Reduviidae, are also known as conenose bugs, kissing bugs (so-called from their habit of feeding from around the mouths of people),[1] or vampire bugs. Other local names for them used in the Americas include barbeiros, vinchucas, pitos, chipos and chinches. Most of the 130 or more species of this subfamily feed on vertebrate blood; a very small portion of species feed on invertebrates.[2][3] They are mainly found and widespread in the Americas, with a few species present in Asia and Africa. These bugs usually share shelter with nesting vertebrates, from which they suck blood. In areas where Chagas disease occurs (from the southern United States to northern Argentina ), all triatomine species are potential vectors of the Chagas disease parasite Trypanosoma cruzi, but only those species that are well adapted to living with humans (such as Triatoma infestans and Rhodnius prolixus) are considered important vectors. Also, proteins released from their bites have been known to induce anaphylaxis in sensitive and sensitized individuals.[4][5]

History

At the beginning of the 19th century, Charles Darwin made one of the first reports of the existence of triatomines in America in his Journal and Remarks, published in 1839 and commonly known as The Voyage of the Beagle. The following is an extract which he based on his journal entry dated 26 March 1835:[6]:315

We crossed the Luxan, which is a river of considerable size, though its course towards the sea-coast is very imperfectly known. It is even doubtful whether, in passing over the plains, it is evaporated, or whether it forms a tributary of the Sauce or Colorado. We slept in the village, which is a small place surrounded by gardens, and forms the most southern part, that is cultivated, of the province of Mendoza; it is five leagues south of the capital. At night I experienced an attack (for it deserves no less a name) of the Benchuca (a species of Reduvius) the great black bug of the Pampas. It is most disgusting to feel soft wingless insects, about an inch long, crawling over one's body. Before sucking they are quite thin, but afterwards they become round and bloated with blood, and in this state are easily crushed. They are also found in the northern parts of Chile and in Peru. One which I caught at Iquique, was very empty. When placed on the table, and though surrounded by people, if a finger was presented, the bold insect would immediately draw its sucker, make a charge, and if allowed, draw blood. No pain was caused by the wound. It was curious to watch its body during the act of sucking, as it changed in less than ten minutes, from being as flat as a wafer to a globular form. This one feast, for which the benchuca was indebted to one of the officers, kept it fat during four whole months; but, after the first fortnight, the insect was quite ready to have another suck.[6]:315
Note: Luxan is a reference to the town/district of Luján de Cuyo, though there is no longer a river named after the town in its vicinity (the only Luján River in present-day Argentina empties into the Río de la Plata and is basically a minor branch of the Rio Paraná); the Benchuca is identified by Richard Keynes as Triatoma infestans which is commonly called the "Vinchuca" bug.[6]

Considerable medical speculation has occurred as to whether or not Darwin's contact with triatomines in Argentina was related to his later bouts of long-term illness, though it is unlikely to have been caused on this specific occasion, as he made no mention of the fever that usually follows the first infection.[6]

Modelling of the geographical distribution of triatomines in Chile shows that Darwin traveled extensively in the areas of central and northern Chile where these bugs occur, sleeping outdoors and in rural houses.[7]


Discovery of triatominae's relation with Chagas disease

In 1909, Brazilian doctor Carlos Chagas discovered that these insects were responsible for the transmission of T. cruzi to many of his patients in Lassance, a village located on the banks of the São Francisco River in Minas Gerais (Brazil ). Poor people living there complained of some insects they called barbeiros that bite during the night. Carlos Chagas put his first observations in words:

Knowing the domiciliary habits of the insect, and its abundance in all the human habitations of the region, we immediately stayed on, interested in finding out the exact biology of the barbeiro, and the transmission of some parasite to man or to another vertebrate.

Another Brazilian, Herman Lent, former student of Carlos Chagas, became devoted to the research of the triatomines and together with Peter Wygodzinsky made a revision of the Triatominae, a summary of 40 years of studies on the triatomines up to 1989.[8]

Biological aspects

Rhodnius prolixus nymphs and adult

Lifecycle

Triatomines undergo incomplete metamorphosis. A wingless first-instar nymph hatches from an egg, and may be small as 2 mm. It passes successively through second, third, fourth, and fifth instars. Finally, the fifth instar turns into an adult, acquiring two pairs of wings.[9]

Ecology

All triatomine nymph instars and adults are haematophagous and require the stability of a sheltered environment, where they aggregate. Most species are associated with wild, nesting vertebrates and are named "sylvatic" triatomines. These live in ground burrows with rodents or armadillos,[10] or in tree dwellings with bats, birds, sloths, or opossums. Few species (5%) live in human dwellings or in the surroundings of human houses (peridomicile) in the shelters of domestic animals, these are named "domestic" species. Many sylvatic species are in process of domiciliation (i.e. "semidomestic").

Behavior

Most triatomines aggregate in refuges during day and search for blood during night, when the host is asleep and the air is cooler. Odors and heat guide these insects to their hosts. Carbon dioxide emanating from breath, as well as ammonia, short-chain amines, and carboxylic acids from skin, hair, and exocrine glands from vertebrate animals, are among the volatiles that attract triatomines.[11] Vision also serves triatomines for orientation. At night, adults of diverse species fly to houses attracted by light.[citation needed]

Adults produce a pungent odor (isobutyric acid) when disturbed, and are also capable of producing a particular sound by rubbing the rostrum over a stridulatory sulcus under its head (stridulation).[citation needed]

Epidemiology

Domestic and sylvatic species can carry the Chagas parasite to humans and wild mammals; birds are immune to the parasite. T. cruzi transmission is carried mainly from human to human by domestic kissing bugs; from the vertebrate to the bug by blood, and from the bug to the vertebrate by the insect's feces, and not by its saliva as occurs in most bloodsucking arthropod vectors such as malaria mosquitoes.[citation needed]

Triatomine infestation especially affects older dwellings. One can recognize the presence of triatomines in a house by its feces, exuviae, eggs, and adults. Triatomines characteristically leave two kinds of feces like strikes on walls of infected houses; one is white with uric acid, and the other is dark (black) containing heme. Whitish or pinkish eggs can be seen in wall crevices. After having had a blood meal, the insects sometimes show a limited mobility and can be identified easily.[citation needed]

Controlling triatomine infestations

Insecticide treatment

Synthetic pyrethroids are the main class of insecticides used to control triatominae infestations. Insecticide treatment is more effective on nonporous surfaces, such as hardwood timber, fired bricks, and plastered walls, than on porous surfaces such as mud. A single treatment with insecticide typically protects against triatomine infestation for a year or more on timber walls vs. 2–3 months on adobe walls. Wettable powders, suspension concentrates, and insecticide paints can improve treatment effectiveness on porous surfaces.

Rates of insecticide resistance among triatomines are fairly low due to their long lifecycle and low genetic variability, but some instances of resistance have been reported, particularly among Triatoma infestans populations in Bolivia and Argentina.[12]

Tribes, genera, and numbers of described species

The monophyly of Triatominae is strongly supported by molecular data, indicating that hematophagy has evolved only once within the Reduviidae.[13] The classification within the subfamily is not stable, with different proposed relationships among the tribes and genera. The classification below largely follows Galvão et al. 2003,[14] but in 2009 this same author eliminated the tribe Linshcosteini and also eliminated the genera Meccus, Mepraia, and Nesotriatoma.[15]

Alberproseniini (monotypic)

Bolboderini

Cavernicolini (monotypic)

Linshcosteini (monotypic)

Rhodniini

Triatomini

In addition, at least three fossil species have been described from amber deposits, one in Myanmar and two in the Dominican Republic:

Most important vectors

All 138 triatomine species are potentially able to transmit T. cruzi to humans, but these five species are the most epidemiologically important vectors of Chagas disease:

See also

  • Hematophagy

References

  1. The dictionary definition of kissing bug at Wiktionary
  2. Sandoval, C.M.; Joya, M.I.; Gutiérrez, R.; Angulo, V.M. (2000). "Cleptohaematophagy of the Triatominae bug Belminus herreri". Medical and Veterinary Entomology 14 (1): 100–1. doi:10.1046/j.1365-2915.2000.00210.x. PMID 10759319. 
  3. Sandoval, C.M.; Duarte, R.; Gutiérrez, R.; Rocha, D.S.; Angulo, V.M.; Esteban, L.; Reyes, M.; Jurberg, J. et al. (2004). "Feeding sources and natural infection of Belminus herreri (Hemiptera, Reduviidae, Triatominae) from dwellings in Cesar, Colombia". Memórias do Instituto Oswaldo Cruz 99 (2): 137–140. doi:10.1590/S0074-02762004000200004. PMID 15250465. 
  4. The EAACI Food Allergy and Anaphylaxis Guidelines Group (August 2014). "Anaphylaxis: guidelines from the European Academy of Allergy and Clinical Immunology". Allergy 69 (8): 1026–45. doi:10.1111/all.12437. PMID 24909803. 
  5. Klotz, JH; Dorn, PL; Logan, JL; Stevens, L; Pinnas, JL; Schmidt, JO; Klotz, SA (Jun 15, 2010). ""Kissing bugs": potential disease vectors and cause of anaphylaxis". Clinical Infectious Diseases 50 (12): 1629–34. doi:10.1086/652769. PMID 20462351. 
  6. 6.0 6.1 6.2 6.3 Keynes, Richard Darwin (1988). Charles Darwin's Beagle Diary. Cambridge, UK: The press syndicate of the University of Cambridge. ISBN 0-521-23503-0. http://darwin-online.org.uk/content/frameset?itemID=F1925&viewtype=text&pageseq=1. Retrieved 9 December 2015. 
  7. Botto-Mahan, Carezza; Medel, Rodrigo (2022-03-24). "Was Chagas disease responsible for Darwin's illness? The overlooked eco-epidemiological context in Chile". Revista Chilena de Historia Natural 94. doi:10.1186/s40693-021-00104-4. https://www.scielo.cl/scielo.php?pid=S0716-078X2021000100501&script=sci_arttext. 
  8. Lent, Herman; Wygodzinsky, Pedro W. (1979). "Revision of the Triatominae (Hemiptera, Reduviidae), and their significance as vectors of Chagas' disease". Bulletin of the American Museum of Natural History 163. 
  9. "Global Health – Division of Parasitic Diseases and Malaria". https://www.cdc.gov/parasites/chagas/gen_info/vectors/triatomine_stages_lg.html. 
  10. Rozendaal, Jan A. (1997). Vector control: Methods for use by individuals and communities. World Health Organization. p. 215. ISBN 92-4-154-494-5. https://www.who.int/water_sanitation_health/resources/vectorcontrol/en/. Retrieved 9 December 2015. 
  11. Manrique, Gabriel; Lorenzo, Marcelo (2012-04-05). "The Sexual Behaviour of Chagas' Disease Vectors: Chemical Signals Mediating Communication between Male and Female Triatomine Bugs" (in en). Psyche: A Journal of Entomology 2012: e862891. doi:10.1155/2012/862891. ISSN 0033-2615. 
  12. Pessoa, Grasielle Caldas Dávila; Vinãs, Pedro Albajar; Rosa, Aline Cristine Luiz; Diotaiuti, Liléia (2015). "History of insecticide resistance of Triatominae vectors". Revista da Sociedade Brasileira de Medicina Tropical 48 (4): 380–389. doi:10.1590/0037-8682-0081-2015. PMID 26312926. 
  13. Weirauch, Christiane; Munro, James B. (2009). "Molecular phylogeny of the assassin bugs (Hemiptera: Reduviidae), based on mitochondrial and nuclear ribosomal genes". Molecular Phylogenetics and Evolution 53 (1): 287–299. doi:10.1016/j.ympev.2009.05.039. PMID 19531379. https://www.researchgate.net/publication/222917431.  Alt URL
  14. Galvão, Cleber; Carcavallo, Rodolfo; Rocha, Dayse DA Silva; Jurberg, José (2003). "A checklist of the current valid species of the subfamily Triatominae Jeannel, 1919 (Hemiptera, Reduviidae) and their geographical distribution, with nomenclatural and taxonomic notes". Zootaxa 202: 1. doi:10.11646/zootaxa.202.1.1. 
  15. Schofield, C. J.; Galvão, Cleber (2009-05-01). "Classification, evolution, and species groups within the Triatominae". Acta Tropica. The Biology of Triatominae - Vectors of Chagas Disease 110 (2): 88–100. doi:10.1016/j.actatropica.2009.01.010. ISSN 0001-706X. https://www.sciencedirect.com/science/article/pii/S0001706X0900028X. 
  16. Poinar, George (March 2005). "Triatoma dominicana sp. n. (Hemiptera: Reduviidae: Triatominae), and Trypanosoma antiquus sp. n. (Stercoraria: Trypanosomatidae), the First Fossil Evidence of a Triatomine-Trypanosomatid Vector Association" (in en). Vector-Borne and Zoonotic Diseases 5 (1): 72–81. doi:10.1089/vbz.2005.5.72. ISSN 1530-3667. PMID 15815152. https://www.liebertpub.com/doi/10.1089/vbz.2005.5.72. 
  17. Poinar, George (January 2019). "A primitive triatomine bug, Paleotriatoma metaxytaxa gen. et sp. nov. (Hemiptera: Reduviidae: Triatominae), in mid-Cretaceous amber from northern Myanmar" (in en). Cretaceous Research 93: 90–97. doi:10.1016/j.cretres.2018.09.004. Bibcode2019CrRes..93...90P. https://linkinghub.elsevier.com/retrieve/pii/S019566711830096X. 
  18. Poinar, George (2013). "Panstrongylus hispaniolae sp. n. (Hemiptera: Reduviidae: Triatominae), a new fossil triatomine in Dominican amber, with evidence of gut flagellates". Paleodiversity (Stuttgart) 6: 1–8. https://www.palaeodiversity.org/pdf/06/S-01_Poinar.pdf. Retrieved 2023-04-02. 

Further reading

  • Brenner RR, Stoka AM (1987) Chagas’ disease vectors. I, II and III. CRC Press. Boca Ratón
  • Dujardin JP, Schofield CJ, Panzera F (2000) "Les vecteurs de la maladie de Chagas: recherches taxonomiques, biologiques et génétiques". Academie Royale des Sciences d'Ultre-Mer. Belgium.

External links

Wikidata ☰ Q13381446 entry