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Antifeedant

From Wikipedia, the free encyclopedia
Compounds produced by plants to stop insects feeding on them

Antifeedants are chemicals produced by plants (phytochemicals) which repel insects through distaste. Alternative names for antifeedants are: antifeeding compounds, feeding deterrents, feeding rejectants, feeding suppressants, feeding inhibitors, gustatory repellents, phagodepressants, anorexigenics and anti-appetants.[1] [2] [3]

Definition

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Antifeedants are most generally defined as chemicals that act at low concentrations and are perceived by specialized taste receptors (gustatory receptors).[3] [4] Other definitions both narrower and broader appear in the literature.[3]

A chemical that repels insects though smell rather than taste, acting on the insect’s smell receptors (olfactory receptors), is defined as a repellent and is not usually characterised as an antifeedant.[5] [6] Insecticidal compounds produced by plants will obviously stop an insect from feeding, but these are not classified as antifeedants. It is however possible that a chemical may act as an antifeedant against one species and as an insecticide against another (see azadirachtin).

The production of antifeedants is one of several mechanisms plants use to stop herbivores eating them.

Not all plants produce antifeedants. Since they are not essential for the life of a plant, they are classed as secondary metabolites.

Antifeedants are signalling molecules (semiochemicals). Since they are advantageous to the producing organism (plant) to the detriment of another organism (insect) they are classed as allomones.

Biochemical mode of action

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Insects have sweet, bitter, sour, salty and umami taste (gustatory) receptors, as do humans.[7] [8] [9] In general compounds that are sweet or bitter to a human are sweet or bitter to insects.[8] Antifeedants may activate a receptor (e.g. bitter receptor) causing distaste or may block a receptor which would stimulate feeding (e.g. sweet receptor) causing the insect to look elsewhere for a suitable food source.[3] Many antifeedants are bitter.[3]

Insects have gustatory receptors on various parts of the body, not only on the mouth parts.[9] Some can taste with their feet (tarsi). An insect moving away after detecting an antifeedant with its tarsi and without biting into the plant is sometimes referred to as an irritant mechanism[6] or a suppressant.[3]

Insects can become habituated to antifeedants and can even evolve over generations to use ‘repellents’ to identify plants for consumption.[8]

Chemical types

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Koul lists about 900 compounds with antifeedant activity.[10] Antifeedants can be found among all the major classes of secondary metabolites. However, the most potent antifeedants are terpenoids. This is also the group with the greatest number and diversity of known antifeedants. Amongst terpenoids, limonoids are well studied and the most potent example is azadirachtin A.[3]

Agricultural use

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The only antifeedant used commercially is azadirachtin containing extracts from the neem tree, Azadirachta indica , although the insecticidal activity is more relevant than the antifeedant activity.[11]




These chemical compounds are typically classified as secondary metabolites in that they are not essential for the metabolism of the plant, but instead confer longevity. Antifeedants exhibit a wide range of activities and chemical structures as biopesticides.[12] Antifeedants and their synthetic analogues are employed on scale for crop production.[13]


Limonoids such as limonin are antifeedants produced by a number of plants of the families Cucurbitaceae Rutaceae and Meliaceae.[14]

Pyrethrum is the toxic component of chrysanthemum sp, comprising as much as 1% weight. The unusual (cyclopropane-based) structure of this material underpinned a substantial industry on synthetic pyrethroids, modifications of pyrethrum as insecticides.[15]


References

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  1. ^ Purrington, C.B. (2003). "Secondary Products | Antifeedant Substances in Plants". In Thomas, Brian (ed.). Encyclopedia of Applied Plant Sciences (1st ed.). Elsevier. pp. 1140–1145. ISBN 9780122270505.
  2. ^ Purrington, C.B. (2017). "Antifeedant Substances in Plants". In Thomas, Brian; Murray, Brian G; Murphy, Denis J (eds.). Encyclopedia of Applied Plant Sciences (2nd ed.). Academic Press. pp. 364–367. ISBN 9780123948083.
  3. ^ a b c d e f g Koul, Opender (2016). "Chapter 17 - Antifeedant Phytochemicals in Insect Management (so Close yet so Far)". In Omkar (ed.). Ecofriendly Pest Management for Food Security. Academic Press. pp. 525–544. ISBN 9780128032657.
  4. ^ Pavela, Roman; Kovaříková, Kateřina; Novák, Matěj (31 January 2025). "Botanical Antifeedants: An Alternative Approach to Pest Control". Insects. 16 (2): 136.
  5. ^ Deletre, Emilie; Schatz, Bertrand; Bourguet, Denis; Chandre, Fabrice; Williams, Livy; Ratnadass, Alain; Martin, Thibaud (19 May 2016). "Prospects for repellent in pest control: current developments and future challenges". Chemoecology. 26: 127–142.
  6. ^ a b Fernando, S. S. S. T.; Jayasooriya, R. G. P. T.; Samarakoon, Kalpa W.; Wijegunawardana, N. D. Asha D; Alahakoon, Sampath B. (6 November 2024). "Citrus-Based Bio-Insect Repellents—A Review on Historical and Emerging Trends in Utilizing Phytochemicals of Citrus Plants". Journal of Toxicology. 2024. 6179226.
  7. ^ Liman, Emily R.; Zhang, Yali V.; Montell, Craig (March 5, 2014). "Peripheral Coding of Taste". Neuron. 81 (5): 984–1000.
  8. ^ a b c King, B H; Gunathunga, Panchalie B (4 April 2023). "Gustation in insects: taste qualities and types of evidence used to show taste function of specific body parts". Journal of Insect Science. 23 (2): 1–18.
  9. ^ a b King, Bethia H; Gunathunga, Panchalie B (2 February 2023). "Gustation Across the Class Insecta: Body Locations". Annals of the Entomological Society of America. 116 (2): 76–82.
  10. ^ Koul, Opender (2005). Insect antifeedants. CRC Press. ISBN 0-415-33400-4.
  11. ^ Isman, Murray (August 2002). "Insect antifeedants". Pesticide Outlook. 13 (4): 152–157.
  12. ^ Richard N. Bennett; Roger M. Wallsgrove (1994). "Secondary metabolites in plant defence mechanisms". New Phytologist. 127 (4): 617–633. Bibcode:1994NewPh.127..617B. doi:10.1111/j.1469-8137.1994.tb02968.x. PMID 33874382.
  13. ^ Duan, Zhi-Kang; Wang, Xu; Lian, Mei-Ya; Guo, Shan-Shan; Gao, Zhi-Heng; Bai, Ming; Huang, Xiao-Xiao; Song, Shao-Jiang (2024). "Bioassay-Guided and DeepSAT-Driven Precise Mining of Monoterpenoid Coumarin Derivatives with Antifeedant Effects from the Leaves of Ailanthus altissima". Journal of Agricultural and Food Chemistry. 72 (19): 10958–10969. Bibcode:2024JAFC...7210958D. doi:10.1021/acs.jafc.4c01049. PMID 38703118.
  14. ^ Amit Roy and Shailendra Saraf (2006). "Limonoids: Overview of Significant Bioactive Triterpenes Distributed in Plants Kingdom". Biol. Pharm. Bull. 29 (2): 191–201. doi:10.1248/bpb.29.191 . PMID 16462017.
  15. ^ a b Metcalf, Robert L.; Horowitz, Abraham Rami (2014). "Insect Control, 2. Individual Insecticides". Ullmann's Encyclopedia of Industrial Chemistry. pp. 1–94. doi:10.1002/14356007.s14_s01. ISBN 978-3-527-30673-2.

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