Caterpillar

Caterpillars are the larval form of members of the order Lepidoptera (the insect order comprising butterflies and moths). They are mostly herbivorous in food habit, although some species are insectivorous. Caterpillars are voracious feeders and many of them are considered to be pests in agriculture. Many moth species are better known in their caterpillar stages because of the damage they cause to fruits and other agricultural produce.

The etymological origins of the word are from the early 16th century, from Middle English catirpel, catirpeller, probably an alteration of Old North French catepelose: cate, cat (from Latin cattus) + pelose, hairy (from Latin pilōsus).[1]

Contents

Classification

The geometrids, also known as inchworms or loopers, are so named because of the way they move, appearing to measure the earth (the word geometrid means earth-measurer in Greek); the primary reason for this unusual locomotion is the elimination of nearly all the prolegs except the clasper on the terminal segment.

Caterpillars have soft bodies that can grow rapidly between moults. Only the head capsule is hardened. The mandibles are tough and sharp for chewing leaves (this contrasts with most adult Lepidoptera, which have highly reduced or soft mandibles). Behind the mandibles of the caterpillar are the spinnerets, for manipulating silk.

Some larvae of the Hymenoptera order (ants, bees and wasps) can appear like the caterpillars of the lepidoptera. Such larvae are mainly seen in the sawfly family. However while these larvae superficially resemble caterpillars, they can be distinguished by the presence of prolegs on every abdominal segment, an absence of crochets or hooks on the prolegs (these are present on lepidopteran caterpillars), prominent ocelli on the head capsule, and an absence of the upside-down Y-shaped suture on the front of the head.[2]

Defenses

Many animals feed on caterpillars as they are rich in protein. As a result caterpillars have evolved various means of defense. The appearance of a caterpillar can often repel a predator: its markings and certain body parts can make it seem poisonous, or bigger in size and thus threatening, or non-edible. Some types of caterpillars are indeed poisonous, and are capable of shooting acid.

Some caterpillars have long "whip-like" organs attached to the ends of their body. The caterpillar wiggles these organs to frighten away flies.[3]

Caterpillars have evolved defenses against physical conditions such as cold, hot or dry environmental conditions. Some Arctic species like Gynaephora groenlandica have special basking and aggregation behaviours[4] apart from physiological adaptations to remain in a dormant state.[5]

Appearance

Many caterpillars are cryptically coloured and resemble the plants on which they feed and may even have parts that mimic plant parts such as thorns. Their size varies from as little as 1 mm to about 3 inches (76 mm). Some look like objects in the environment such as bird droppings. Many feed enclosed inside silk galleries, rolled leaves or by mining between the leaf surfaces. Caterpillars of Nemoria arizonaria that grow in spring feed on oak catkins and appear green. The summer brood appear like oak twigs. The differential development is linked to the tannin content in the diet.[6]

More aggressive self-defense measures are taken by some caterpillars. These measures include having spiny bristles or long fine hair-like setae with detachable tips that will irritate by lodging in the skin or mucous membranes.[2] However some birds (such as cuckoos) will swallow even the hairiest of caterpillars. The most aggressive caterpillar defenses are bristles associated with venom glands. These bristles are called urticating hairs. A venom which is among the most potent defensive chemicals in any animal is produced by the South American silk moth genus Lonomia. Its venom is an anticoagulant powerful enough to cause a human to hemorrhage to death (See Lonomiasis).[7] This chemical is being investigated for potential medical applications. Most urticating hairs range in effect from mild irritation to dermatitis.

Plants contain toxins which protect them from herbivores, but some caterpillars have evolved countermeasures which enable them to eat the leaves of such toxic plants. In addition to being unaffected by the poison, the caterpillars sequester it in their body, making them highly toxic to predators. The chemicals are also carried on into the adult stages. These toxic species, such as the Cinnabar moth (Tyria jacobaeae) and monarch (Danaus plexippus) caterpillars, usually advertise themselves with the danger colors of red, yellow and black, often in bright stripes (see aposematism). Any predator that attempts to eat a caterpillar with an aggressive defence mechanism will learn and avoid future attempts.

Some caterpillars regurgitate acidic digestive juices at attacking enemies. Many papilionid larvae produce bad smells from extrudable glands called osmeteria.

Caterpillars can evade predators by using a silk line and dropping off from branches when disturbed.

Some caterpillars obtain protection by associating themselves with ants. The Lycaenid butterflies are particularly well known for this. They communicate with their ant protectors by vibrations as well as chemical means and typically provide food rewards.[8]

Some caterpillars are gregarious; large aggregations are believed to help in reducing the levels of parasitization and predation.[9] Clusters amplify the signal of aposematic coloration, and individuals may participate in group regurgitation or displays.

Caterpillars can be confused with the larvae of sawflies (see image on right). Lepidopteran larvae can be differentiated by:

Behavior

Caterpillars have been called "eating machines", and eat leaves voraciously. Most species shed their skin four or five times as their bodies grow, and they eventually pupate into an adult form.[10] Caterpillars grow very quickly; for instance, a tobacco hornworm will increase its weight ten-thousandfold in less than twenty days. An adaptation that enables them to eat so much is a mechanism in a specialized midgut that quickly transports ions to the lumen (midgut cavity), to keep the potassium level higher in the midgut cavity than in the blood.[11]

Most caterpillars are solely herbivorous. Many are restricted to one species of plant, while others are polyphagous. A few, including the clothes moth, feed on detritus. Most predatory caterpillars feed on eggs of other insects, aphids, scale insects, or ant larvae. Some are cannibals, and others prey on caterpillars of other species (e.g. Hawai'ian Eupithecia ). A few are parasitic on cicadas or leaf hoppers.[12] Some Hawai'ian caterpillars (Hyposmocoma molluscivora) use silk traps to capture snails.[13]

Many caterpillars are nocturnal. For example, the "cutworms" (of the Noctuidae family) hide at the base of plants during the day and only feed at night.[14] Others, such as gypsy moth (Lymantria dispar) larvae, change their activity patterns depending on density and larval stage, with more diurnal feeding in early instars and high densities.[15]

Economic effects

Caterpillars cause much damage, mainly by eating leaves. The propensity for damage is enhanced by monocultural farming practices, especially where the caterpillar is specifically adapted to the host plant under cultivation. The cotton bollworm causes enormous losses. Other species eat food crops. Caterpillars have been the target of pest control through the use of pesticides, biological control and agronomic practices. Many species have become resistant to pesticides. Bacterial toxins such as those from Bacillus thuringiensis which are evolved to affect the gut of Lepidoptera have been used in sprays of bacterial spores, toxin extracts and also by incorporating genes to produce them within the host plants. These approaches are defeated over time by the evolution of resistance mechanisms in the insects.[16]

Plants evolve mechanisms of resistance to being eaten by caterpillars, including the evolution of chemical toxins and physical barriers such as hairs. Incorporating host plant resistance (HPR) through plant breeding is another approach used in reducing the impact of caterpillars on crop plants.[17]

Some caterpillars are used in industry. The silk industry is based on the silkworm caterpillar.

Human health

Caterpillar hair can be a cause of human health problems. Caterpillar hairs sometimes have venoms in them and species from approximately 12 families of moths or butterflies worldwide can inflict serious human injuries ranging from urticarial dermatitis and atopic asthma to osteochondritis, consumption coagulopathy, renal failure, and intracerebral hemorrhage.[18] Skin rashes are the most common, but there have been fatalities.[19] Lonomia is a frequent cause of envenomation in Brazil, with 354 cases reported between 1989 and 2005. Lethality ranging up to 20% with death caused most often by intracranial hemorrhage.[20]

Caterpillar hairs have also been known to cause kerato-conjunctivitis. The sharp barbs on the end of caterpillar hairs can get lodged in soft tissues and mucus membranes such as the eyes. Once they enter such tissues, they can be difficult to extract, often exacerbating the problem as they migrate across the membrane.[21]

This becomes a particular problem in an indoor setting. The hairs easily enter buildings through ventilation systems and accumulate in indoor environments because of their small size, which makes it difficult for them to be vented out. This accumulation increases the risk of human contact in indoor environments.[22]

See also

References

  1. ^ "Caterpillar". Dictionary.com. The American Heritage Dictionary of the English Language, Fourth Edition. Houghton Mifflin Company, 2004. (accessed: March 26, 2008).
  2. ^ a b Scoble, MJ. 1995. The Lepidoptera: Form, function and diversity. Oxford Univ. Press. ISBN 0198549520
  3. ^ Darby, Gene (1958). What is a Butterfly. Chicago: Benefic Press. p. 13. 
  4. ^ Kukal, O., B. Heinrich, and J. G. Duman (1988). "Behavioral thermoregulation in the freeze-tolerant arctic caterpillar, Gynaeophora groenlandica". J. Exper. Biol. 138 (1): 181–193. http://jeb.biologists.org/cgi/content/abstract/138/1/181. 
  5. ^ Bennett, V. A. Lee, R. E. Nauman, L. S. Kukal, O. (2003). "Selection of overwintering microhabitats used by the arctic woollybear caterpillar, Gynaephora groenlandica". Cryo Letters 24 (3): 191–200. PMID 12908029. http://www.units.muohio.edu/cryolab/publications/documents/BennettLeeetal03.pdf. 
  6. ^ Greene, E (1989). "A Diet-Induced Developmental Polymorphism in a Caterpillar". Science 243 (4891): 643–646. doi:10.1126/science.243.4891.643. PMID 17834231. 
  7. ^ Malaque, Ceila M. S., Lúcia Andrade, Geraldine Madalosso, Sandra Tomy, Flávio L. Tavares, And Antonio C. Seguro. (2006). "A case of hemolysis resulting from contact with a Lonomia caterpillar in southern Brazil". Am. J. Trop. Med. Hyg. 74 (5): 807–809. PMID 16687684. http://www.ajtmh.org/cgi/content/full/74/5/807. 
  8. ^ Australian museum
  9. ^ Entry, Grant L. G., Lee A. Dyer. (2002). "On the Conditional Nature Of Neotropical Caterpillar Defenses against their Natural Enemies". Ecology 83 (11): 3108–3119. doi:10.1890/0012-9658(2002)083[3108:OTCNON]2.0.CO;2. JSTOR 3071846. 
  10. ^ Monarch Butterfly
  11. ^ Chamberlin, M.E. and M.E. King (1998). "Changes in midgut active ion transport and metabolism during the fifth instar of the tobacco hornworm (Manduca sexta)". J. Exp. Zool. 280 (2): 135–141. doi:10.1002/(SICI)1097-010X(19980201)280:2<135::AID-JEZ4>3.0.CO;2-P. 
  12. ^ Pierce, N.E. (1995). "Predatory and parasitic Lepidoptera: Carnivores living on plants". Journal of the Lepidopterist's Society 49 (4): 412–453. 
  13. ^ Rubinoff, D; Haines, WP (2005). "Web-spinning caterpillar stalks snails". Science 309 (5734): 575. doi:10.1126/science.1110397. PMID 16040699. 
  14. ^ "Caterpillars of Pacific Northwest Forests and Woodlands". USGS. http://www.npwrc.usgs.gov/resource/insects/catnw/ecol.htm. 
  15. ^ Lance, D. R.; Elkinton, J. S.; Schwalbe, C. P. (1987). "Behaviour of late-instar gypsy moth larvae in high and low density populations". Ecological Entomology 12 (3): 267. doi:10.1111/j.1365-2311.1987.tb01005.x. 
  16. ^ Tent Caterpillars and Gypsy Moths
  17. ^ van Emden, H. F. (1999). "Transgenic Host Plant Resistance to Insects—Some Reservations". Annals of the Entomological Society of America 92 (6): 788–797. http://www.ingentaconnect.com/content/esa/aesa/1999/00000092/00000006/art00002. 
  18. ^ Diaz, HJ (2005). "The evolving global epidemiology, syndromic classification, management, and prevention of caterpillar envenoming". Am. J. Trop. Med. Hyg. 72 (3): 347–357. PMID 15772333. 
  19. ^ Redd, JT; Voorhees, RE; Török, TJ (2007). "Outbreak of lepidopterism at a Boy Scout camp". Journal of the American Academy of Dermatology 56 (6): 952–955. doi:10.1016/j.jaad.2006.06.002. PMID 17368636. 
  20. ^ Kowacs, PA; Cardoso, J; Entres, M; Novak, EM; Werneck, LC (December 2006). "Fatal intracerebral hemorrhage secondary to Lonomia obliqua caterpillar envenoming: case report". Arquivos de neuro-psiquiatria 64 (4): 1030–2. doi:10.1590/S0004-282X2006000600029. PMID 17221019. http://www.scielo.br/scielo.php?script=sci_arttext&pid=S0004-282X2006000600029&lng=en&nrm=iso&tlng=en. 
  21. ^ Patel RJ, Shanbhag RM (1973). "Ophthalmia nodosa – (a case report)". Indian J Ophthalmol 21 (4): 208. http://www.ijo.in/article.asp?issn=0301-4738;year=1973;volume=21;issue=4;spage=208;epage=208;aulast=Patel. 
  22. ^ Corrine R Balit, Helen C Ptolemy, Merilyn J Geary, Richard C Russell and Geoffrey K Isbister, CR (2001). "Outbreak of caterpillar dermatitis caused by airborne hairs of the mistletoe browntail moth (Euproctis edwardsi)". The Medical journal of Australia 175 (11–12): 641–3. ISSN 0025-729X. PMID 11837874. http://www.mja.com.au/public/issues/175_12_171201/balit/balit.html. 

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