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Toxungen

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Experimentally induced toxungen spraying by the scorpion Parabuthus transvaalicus.

Toxungen comprises a secretion or other body fluid of one or more biological toxins that is transferred by one animal to the external surface of another animal via a physical delivery mechanism.[1] Toxungens can be delivered through spitting, spraying, or smearing. As one of three categories of biological toxins, toxungens can be distinguished from poisons, which are passively transferred via ingestion, inhalation, or absorption across the skin, and venoms, which are delivered through a wound generated by a bite, sting, or other such action.[2] Toxungen use offers the evolutionary advantage of delivering toxins into the target's tissues without the need for physical contact.[3]

Taxonomic distribution

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Toxungens have evolved in a variety of animals, including flatworms,[4] insects,[5][6] arachnids,[7] cephalopods,[8] amphibians,[9] and reptiles.[10]

Toxungen use possibly exists in birds, as a number of species deploy defensive secretions from their stomachs, uropygial glands, or cloacas, and some anoint themselves with heterogenously acquired chemicals from millipedes, caterpillars, beetles, plant materials, and even manufactured pesticides.[11][12] Some of the described substances may be toxic, at least to ectoparasites, which would qualify them as toxungens.

Toxungen use might also exist in several mammal groups. Slow lorises (genus Nycticebus), which comprise several species of nocturnal primates in Southeast Asia, produce a secretion in their brachial glands (a scent gland near their armpit) that possesses apparent toxicity.[13][14][15] When the secretion is licked and combined with saliva, their bite introduces the secretion into a wound, which can cause sometimes severe tissue injury to conspecifics and other aggressors, thereby functioning as a venom. They can also rub the secretion on their fur or lick their offspring before stashing them in a secure location, thereby functioning potentially as a toxungen. Skunks and several other members of Mephitidae and Mustelidae spray a noxious and potentially injurious secretion from their anal sac when threatened.[16] High concentrations of the spray can be toxic,[17] with rare accounts of spray victims suffering injury and even death.[18][19]

Although the extinct theropod Dilophosaurus was portrayed in the original Jurassic Park and Jurassic World Dominion movies as capable of spitting a toxic secretion, no evidence exists to suggest that any dinosaur possessed either a toxungen or venom.[20]

Classification of toxin deployment

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Animals that deploy toxungens are referred to as toxungenous. Some animals use their toxins in multiple ways, and can be classified as poisonous, toxungenous, and/or venomous. Examples include the scorpion Parabuthus transvaalicus, which is both toxungenous (can spray its toxins) and venomous (can inject its toxins),[21][22] and the snake Rhabdophis tigrinus, which is poisonous (sequesters toad and/or firefly toxins in its nuchal gland tissues that are toxic if consumed by a predator), toxungenous (the nuchal glands are pressurized and can spray the toxins when ruptured), and venomous (toxic oral gland secretions can be injected via the teeth).[23] Even humans can be considered facultatively poisonous, toxungenous, and venomous because they sometimes make use of toxins by all three means for research and development (e.g., biomedical purposes), agriculture (e.g., spraying insecticides), and nefarious reasons (to kill other animals, including humans).[24]

Evolution and function

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Toxungen deployment offers a key evolutionary advantage compared to poisons and venoms. Poisons and venoms require direct contact with the target animal, which puts the toxin-possessing animal at risk of injury and death from a potentially dangerous enemy. Evolving the capacity to spit or spray a toxic secretion can reduce this risk by delivering the toxins from a distance.[25]

Toxins used as toxungens can be acquired by several means. Many species synthesize their own toxins and store them within glands, but others acquire their toxins exogenously from other species. Two examples illustrate exogenous acquisition. Snakes of the genus Rhabdophis sequester their nuchal gland toxins from their diet of toads and/or fireflies,[26][27] Blue-ringed octopuses (genus Hapalochlaeana) acquire tetrodotoxin, the highly toxic non-proteinaceous component of their salivary glands that can be ejected into the water to subdue nearby prey, via accumulation from food resources and/or symbiotic tetrodotoxin-producing bacteria.[28][29]

Toxungens are most commonly used for defensive purposes, but can be used in other contexts as well. Examples of toxungen use for predation include the blue-ringed octopus, which can squirt its secretion into water to immobilize or kill its prey,[30] and ants of the genus Crematogaster that cooperatively subdue their prey by seizing, spread-eagling, and then smearing their toxins onto the prey's surface.[31] Toxungens can also be used for communication and hygiene. Many hymenopterans possess a secretion used as a venom (injected for predation and/or defense) that can also be sprayed to communicate alarm among nestmates, to mark a trail used for food gathering, or to keep their brood free of parasites.[32]

Because of their unique delivery system, toxungens may be chemically designed to better penetrate body surfaces. Arthropods that spray or smear their secretion onto insect prey enhance toxin penetration by including a spreading agent that additionally enhances toxicity.[33][34][35] Some Spitting cobras have modified their secretion so that the cardiotoxins are more injurious to eye membranes.[36]

References

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  1. ^ Nelsen, D. R., Nisani, Z., Cooper, A. M., Fox, G. A., Gren, E. C., Corbit, A. G., & Hayes, W. K. (2014). "Poisons, toxungens, and venoms: redefining and classifying toxic biological secretions and the organisms that employ them". Biological Reviews, 89(2), 450-465. doi:10.1111/brv.12062. PMID: 24102715.
  2. ^ Nelsen, D. R., Nisani, Z., Cooper, A. M., Fox, G. A., Gren, E. C., Corbit, A. G., & Hayes, W. K. (2014). "Poisons, toxungens, and venoms: redefining and classifying toxic biological secretions and the organisms that employ them". Biological Reviews, 89(2), 450-465. doi:10.1111/brv.12062. PMID: 24102715.
  3. ^ Nelsen, D. R., Nisani, Z., Cooper, A. M., Fox, G. A., Gren, E. C., Corbit, A. G., & Hayes, W. K. (2014). "Poisons, toxungens, and venoms: redefining and classifying toxic biological secretions and the organisms that employ them". Biological Reviews, 89(2), 450-465. doi:10.1111/brv.12062. PMID: 24102715.
  4. ^ Koopowitz, H. (1970). "Feeding behaviour and the role of the brain in the polyclad flatworm, Planocera gilchristi". Animal Behavior 18, 31–35. doi:10.1016/0003-3472(70)90066-7.
  5. ^ Deml, R. & Dettner, K. (1994). Attacus atlas caterpillars (Lep., Saturniidae) spray an irritant secretion from defensive glands. Journal of Chemical Ecology 20, 2127–2138. doi:10.1007/BF02066249. PMID: 24242735.
  6. ^ Eisner, T., Aneshansley, D. J., Eisner, M., Attygalle, A. B., Alsop, D. W. & Meinwald, J. (2000a). "Spray mechanism of the most primitive bombardier beetle (Metrius contractus)". Journal of Experimental Biology 203, 1265–1275. doi:10.1242/jeb.203.8.1265. PMID: 10729276.
  7. ^ Nisani, Z., & Hayes, W. K. (2015). "Venom-spraying behavior of the scorpion Parabuthus transvaalicus (Arachnida: Buthidae)". Behavioural Processes, 115, 46-52. doi:10.1016/j.beproc.2015.03.002. PMID: 25748565.
  8. ^ Sutherland, S. & Lane, W. (1969). "Toxins and mode of envenomation of the common ringed or blue-banded octopus". Medical Journal of Australia 1, 893–898. doi:10.5694/j.1326-5377.1969.tb49778.x. PMID: 4977737.
  9. ^ Brodie, E. D. & Smatresk,N. J. (1990). "The antipredator arsenal of fire salamanders: spraying of secretions from highly pressurized dorsal skin glands". Herpetologica 46, 1–7. https://www.jstor.org/stable/3892595.
  10. ^ Berthé, R. A., De Pury, S., Bleckmann, H., & Westhoff, G. (2009). "Spitting cobras adjust their venom distribution to target distance". Journal of Comparative Physiology A, 195(8), 753-757. doi:10.1007/s00359-009-0451-6. PMID 19462171.
  11. ^ J.P. Dumbacher and Pruett-Jones, S. (1996). "Avian chemical defense". In: Nolan, V., Jr., and Ketterson, E. D. (Eds.), Current Ornithology, vol. 13, Plenum Press, New York (1996), pp. 137-174. doi:10.1007/978-1-4615-5881-1_4
  12. ^ Morozov, N. S. (2015). Why do birds practice anting? Biology Bulletin Reviews, 5(4), 353-365. doi:10.1134/S2079086415040076
  13. ^ Alterman, L. (1995). "Toxins and toothcombs: potential allospecific chemical defenses in Nycticebus and Perodicticus". In Alterman, L.; Doyle, G.A.; Izard, M.K (eds.). Creatures of the Dark: The Nocturnal Prosimians. New York, New York: Plenum Press. Pp. 413–424. ISBN 978-0-306-45183-6. OCLC 33441731.
  14. ^ Nekaris, K., Moore, R. S., Rode, E. J., & Fry, B. G. (2013). Mad, bad and dangerous to know: the biochemistry, ecology and evolution of slow loris venom. Journal of Venomous Animals and Toxins including Tropical Diseases, 19, 1-10. doi:10.1186/1678-9199-19-21. PMID 31074351.
  15. ^ Nekaris, K. A. I., Campera, M., Nijman, V., Birot, H., Rode-Margono, E. J., Fry, B. G., ... & Imron, M. A. (2020). Slow lorises use venom as a weapon in intraspecific competition. Current Biology, 30(20), R1252-R1253. doi:10.1016/j.cub.2020.08.084. PMID 33080192.
  16. ^ Stankowich, T., Caro, T., & Cox, M. (2011). Bold coloration and the evolution of aposematism in terrestrial carnivores. Evolution, 65(11), 3090-3099. doi:10.1111/j.1558-5646.2011.01334.x. PMID 22023577.
  17. ^ Wood, W. F. (1999). The history of skunk defensive secretion research. The Chemical Educator, 4(2), 44-50. doi:10.1007/s00897990286a.
  18. ^ Zaks, K. L., Tan, E. O., & Thrall, M. A. (2005). Heinz body anemia in a dog that had been sprayed with skunk musk. Journal of the American Veterinary Medical Association, 226(9), 1516-1518. doi:10.2460/javma.2005.226.1516. PMID 15882003.
  19. ^ Fierro, B. R., Agnew, D. W., Duncan, A. E., Lehner, A. F., & Scott, M. A. (2013). Skunk musk causes methemoglobin and Heinz body formation in vitro. Veterinary Clinical Pathology, 42(3), 291-300. doi:10.1111/vcp.12074. PMID 24033800.
  20. ^ Carter, N. Undated. "The real Dilophosaurus." At Blogosaur, Phillip J. Curie Dinosaur Museum.
  21. ^ Nisani, Z., & Hayes, W. K. (2015). "Venom-spraying behavior of the scorpion Parabuthus transvaalicus (Arachnida: Buthidae)". Behavioural Processes, 115, 46-52. doi:10.1016/j.beproc.2015.03.002. PMID: 25748565.
  22. ^ Nisani, Z., & Hayes, W. K. (2011). "Defensive stinging by Parabuthus transvaalicus scorpions: risk assessment and venom metering". Animal Behaviour, 81(3), 627-633. doi:10.1016/j.anbehav.2010.12.010.
  23. ^ Mori, A., Burghardt, G. M., Savitzky, A. H., Roberts, K. A., Hutchinson, D. A., & Goris, R. C. (2012). "Nuchal glands: a novel defensive system in snakes". Chemoecology, 22(3), 187-198. doi:10.1007/s00049-011-0086-2.
  24. ^ Nelsen, D. R., Nisani, Z., Cooper, A. M., Fox, G. A., Gren, E. C., Corbit, A. G., & Hayes, W. K. (2014). "Poisons, toxungens, and venoms: redefining and classifying toxic biological secretions and the organisms that employ them". Biological Reviews, 89(2), 450-465. doi: 10.1111/brv.12062. PMID: 24102715.
  25. ^ Nelsen, D. R., Nisani, Z., Cooper, A. M., Fox, G. A., Gren, E. C., Corbit, A. G., & Hayes, W. K. (2014). "Poisons, toxungens, and venoms: redefining and classifying toxic biological secretions and the organisms that employ them". Biological Reviews, 89(2), 450-465. doi:10.1111/brv.12062. PMID: 24102715.
  26. ^ Hutchinson, D. A., Mori, A., Savitzky, A. H., Burghardt, G. M., Wu, X., Meinwald, J., & Schroeder, F. C. (2007). "Dietary sequestration of defensive steroids in nuchal glands of the Asian snake Rhabdophis tigrinus". Proceedings of the National Academy of Sciences, 104(7), 2265-2270. doi:10.1073/pnas.0610785104. PMID: 17284596.
  27. ^ Fukuda, M., & Mori, A. (2021). "Does an Asian natricine snake, Rhabdophis tigrinus, have chemical preference for a skin toxin of toads?" Current Herpetology, 40(1), 1-9. doi: [doi:10.5358/hsj.40.1 10.5358/hsj.40.1].
  28. ^ Sutherland, S. & Lane, W. (1969). "Toxins and mode of envenomation of the common ringed or blue-banded octopus". Medical Journal of Australia 1, 893–898. doi:10.5694/j.1326-5377.1969.tb49778.x. PMID: 4977737.
  29. ^ Yamate, Y., Takatani, T., & Takegaki, T. (2021). "Levels and distribution of tetrodotoxin in the blue-lined octopus Hapalochlaena fasciata in Japan, with special reference to within-body allocation." Journal of Molluscan Studies, 87(1), eyaa042. doi: [1].
  30. ^ Sutherland, S. & Lane, W. (1969). "Toxins and mode of envenomation of the common ringed or blue-banded octopus". Medical Journal of Australia 1, 893–898. doi:10.5694/j.1326-5377.1969.tb49778.x. PMID: 4977737.
  31. ^ Richard, F. J., Fabre, A. & Dejean, A. (2001). "Predatory behavior in dominant arboreal ant species: the case of Crematogaster sp. (Hymenoptera: Formicidae)". Journal of Insect Behavior 14, 271–282. doi:10.1023/A:1007845929801.
  32. ^ Nelsen, D. R., Nisani, Z., Cooper, A. M., Fox, G. A., Gren, E. C., Corbit, A. G., & Hayes, W. K. (2014). "Poisons, toxungens, and venoms: redefining and classifying toxic biological secretions and the organisms that employ them". Biological Reviews, 89(2), 450-465. doi:10.1111/brv.12062. PMID: 24102715.
  33. ^ Eisner, T., Meinwald, J., Monro, A. & Ghent, R. (1961). "Defence mechanisms of Arthropods. I. The composition and function of the spray of the whipscorpion, Mastigoproctus giganteus (Lucas)(Arachnida, Pedipalpida)". Journal of Insect Physiology 6, 272–298. doi:10.1016/0022-1910(61)90054-3.
  34. ^ Prestwich, G. D. (1984). "Defense-mechanisms of termites". Annual Review of Entomology 29, 201–232. doi:10.1146/annurev.en.29.010184.001221.
  35. ^ Eisner, T., Rossini, C. & Eisner, M. (2000b). "Chemical defense of an earwig (Doru taeniatum)". Chemoecology 10, 81–87. doi:10.1007/s000490050011.
  36. ^ Ismail,M., Al-Bekairi, A.M., El-Bedaiwy, A.M. & Abd-El Salam,M. A. (1993). "The ocular effect of spitting cobras: II. Evidence that cardiotoxins are responsible for the corneal opacification syndrome". Clinical Toxicology 31, 45–62. doi:10.3109/15563659309000373. PMID: 8433415.