Proboscis Explained

A proboscis is an elongated appendage from the head of an animal, either a vertebrate or an invertebrate. In invertebrates, the term usually refers to tubular mouthparts used for feeding and sucking. In vertebrates, a proboscis is an elongated nose or snout.

Etymology

First attested in English in 1609 from Latin Latin: proboscis, the latinisation of the Ancient Greek Greek, Ancient (to 1453);: προβοσκίς (Greek, Ancient (to 1453);: proboskis),^[1] which comes from Greek, Ancient (to 1453);: πρό (Greek, Ancient (to 1453);: pro) 'forth, forward, before'^[2] + Greek, Ancient (to 1453);: βόσκω (Greek, Ancient (to 1453);: bosko), 'to feed, to nourish'.^[3] The plural as derived from the Greek is Greek, Ancient (to 1453);: proboscides, but in English the plural form proboscises occurs frequently.

Invertebrates

The most common usage is to refer to the tubular feeding and sucking organ of certain invertebrates such as insects (e.g., moths, butterflies, and mosquitoes), worms (including Acanthocephala, proboscis worms) and gastropod molluscs.

Acanthocephala

The Acanthocephala, the thorny-headed worms or spiny-headed worms, are characterized by the presence of an eversible proboscis, armed with spines, which they use to pierce and hold the gut wall of their host.

Lepidoptera mouth parts

The mouth parts of Lepidoptera (butterflies and moths) mainly consist of the sucking kind; this part is known as the proboscis or 'haustellum'. The proboscis consists of two tubes held together by hooks and separable for cleaning. The proboscis contains muscles for operating. Each tube is inwardly concave, thus forming a central tube up which moisture is sucked. Suction takes place due to the contraction and expansion of a sac in the head.^[4] A specific example of the proboscis being used for feeding is in the species Deilephila elpenor. In this species, the moth hovers in front of the flower and extends its long proboscis to attain its food.^[5]

A few Lepidoptera species lack mouth parts and therefore do not feed in the imago. Others, such as the family Micropterigidae, have mouth parts of the chewing kind.^[6]

The study of insect mouthparts was helpful for the understanding of the functional mechanism of the proboscis of butterflies (Lepidoptera) to elucidate the evolution of new form-function.^{[7] [8]} The study of the proboscis of butterflies revealed surprising examples of adaptations to different kinds of fluid food, including nectar, plant sap, tree sap, dung^{[9] [10] [11]} and of adaptations to the use of pollen as complementary food in Heliconius butterflies.^{[12] [13]} An extremely long proboscis appears within different groups of flower-visiting insects, but is relatively rare.

Gastropods

Some evolutionary lineages of gastropods have evolved a proboscis. In gastropods, the proboscis is an elongation of the snout with the ability to retract inside the body; it can be used for feeding, sensing the environment, and in some cases, capturing prey or attaching to hosts. Three major types of proboscises have been identified: pleurembolic (partially retractable), acrembolic (fully retractable), and intraembolic (variable in structure). Acrembolic proboscises are usually found in parasitic gastropods.^{[14] [15]}

Vertebrates

The elephant's trunk and the tapir's elongated nose are called "proboscis", as is the snout of the male elephant seal.

Notable mammals with some form of proboscis are:

• Aardvark
• Anteater
• Elephant
• Elephant shrew
• Hispaniolan solenodon
• Echidna
• Elephant seal
• Leptictidium (extinct)
• Moeritherium (extinct)
• Numbat
• Proboscis monkey
• Saiga antelope
• Members of the tapir family

The proboscis monkey is named for its enormous nose.

The human nose is sometimes called a proboscis, especially when large or prominent.

Notes and References

1. https://www.perseus.tufts.edu/hopper/text?doc=Perseus%3Atext%3A1999.04.0057%3Aentry%3Dproboski%2Fs προβοσκίς
2. https://www.perseus.tufts.edu/hopper/text?doc=Perseus%3Atext%3A1999.04.0057%3Aentry%3Dpro%2F πρό
3. https://www.perseus.tufts.edu/hopper/text?doc=Perseus%3Atext%3A1999.04.0057%3Aentry%3Dbo%2Fskw βόσκω
4. Evans, W. H. (1927) Identification of Indian Butterflies, The Diocesan press. Introduction, pp. 1–35.
5. Book: From Animals to Animats 7: Proceedings of the Seventh International Conference on Simulation of Adaptive Behavior. Hallam. Bridget. Floreano. Dario. Hallam. John. Hayes. Gillian. Meyer. Jean-Arcady. 2002. MIT Press. 9780262582179. en.
6. Charles A. Triplehorn and Norman F. Johnson (2005). Borror and Delong's Introduction to the Study of Insects (7th edition). Thomson Brooks/Cole, Belmont, CA.
7. Krenn HW, Kristensen NP . 2000. Early evolution of the proboscis of Lepidoptera: external morphology of the galea in basal glossatan moths, with remarks on the origin of the pilifers. Zoologischer Anzeiger . 239. 179–196.
8. Krenn HW, Kristensen NP . 2004. Evolution of proboscis musculature in Lepidoptera. European Journal of Entomology . 101. 4. 565–575. 10.14411/eje.2004.080. free.
9. Proboscis morphology and food preferences in Nymphalidae (Lepidoptera, Papilionoidea). J. Zool. Lond.. 2001. 253. 17–26. Krenn HW, Zulka KP, Gatschnegg T . 10.1017/S0952836901000528.
10. Efficiency of fruit juice feeding in Morpho peleides (Nymphalidae, Lepidoptera). Journal of Insect Behavior. 16. 67–77. 10.1023/A:1022849312195. 2003. Knopp. M. C. N.. Krenn. H. W.. 33428687.
11. 10.1146/annurev-ento-112408-085338. 19961330. 4040413. Feeding Mechanisms of Adult Lepidoptera: Structure, Function, and Evolution of the Mouthparts. Annual Review of Entomology. 55. 307–27. 2010. Krenn. Harald W..
12. Mechanical damage to pollen aids nutrient acquisition in Heliconius butterflies (Nymphalidae). Arthropod-Plant Interactions. 3. 4. 203–208. 10.1007/s11829-009-9074-7. 24900162. 2009. Krenn. Harald W.. Eberhard. Monika J. B.. Eberhard. Stefan H.. Hikl. Anna-Laetitia. Huber. Werner. Gilbert. Lawrence E.. Lawrence E. Gilbert. 4040415.
13. 22208893. 3281465. Pollen processing behavior of Heliconius butterflies: A derived grooming behavior. Journal of Insect Science. 11. 99. 99. 2011. Hikl. A. L.. Krenn. H. W.. 10.1673/031.011.9901.
14. Malacopedia. 2595-9913. Volume 2(4): 22-29. Simone. Luiz. September 2019. The proboscis of the Gastropoda 1: its evolution.
15. Journal of Molluscan Studies. Ball, A.D. and Andrews, E.B. and Taylor, J.D.. THE ONTOGENY OF THE PLEUREMBOLIC PROBOSCIS IN NUCELLA LAPILLUS (GASTROPODA: MURICIDAE) . 63. 1. 87–89. 1997-02-01. 10.1093/mollus/63.1.87 . 0260-1230.