Fishes learn aversions to a nudibranchs chemical defense

Long, Jeremy D.; Hay, Mark E.

doi:10.3354/meps307199

Cited by 39 publications

(21 citation statements)

References 58 publications

(65 reference statements)

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“…Some predators learn to avoid sea slugs on the basis of odor. Fish are one example, and they learn in different ways to avoid the chemically defended nudibranch Doriopsilla pharpa (Long and Hay, 2006). One fish, the mummichog Fundulus heteroclitus, learns to specifically avoid sea hares via a sesquiterpene, polygodial.…”

Section: Al 2000)mentioning

confidence: 99%

“…One fish, the mummichog Fundulus heteroclitus, learns to specifically avoid sea hares via a sesquiterpene, polygodial. In the study by Long and Hay (2006), mummichogs initially ate food containing this compound and learned to avoid food containing it, but they continued to eat foods initially associated with this compound (specific learned aversion). Another fish, the striped blenny Chasmodes bosquianus, also initially ate food containing polygodial and learned quickly to avoid food containing it; however, this species avoided food that was initially associated with polygodial but no longer contained it (generalized learned aversion).…”

Section: Al 2000)mentioning

confidence: 99%

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Escape by Inking and Secreting: Marine Molluscs Avoid Predators Through a Rich Array of Chemicals and Mechanisms

Derby

2007

The Biological Bulletin

128

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Inking by marine molluscs such as sea hares, cuttlefish, squid, and octopuses is a striking behavior that is ideal for neuroecological explorations. While inking is generally thought to be used in active defense against predators, experimental evidence for this view is either scant or lacks mechanistic explanations. Does ink act through the visual or chemical modality? If inking is a chemical defense, how does it function and how does it affect the chemosensory systems of predators? Does it facilitate escape not only by acting directly on predators but also by being an alarm signal for conspecifics? This review examines these issues, within a broader context of passive and active chemical defensive secretions. It focuses on recent work on mechanisms of defense by inking in sea hares (Aplysia) and extends what we have learned about sea hares to other molluscs including the cephalopods.

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Section: Al 2000)mentioning

confidence: 99%

Section: Al 2000)mentioning

confidence: 99%

Escape by Inking and Secreting: Marine Molluscs Avoid Predators Through a Rich Array of Chemicals and Mechanisms

Derby

2007

The Biological Bulletin

128

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“…Some marine natural products have been studied for their toxicity to nervous systems, but few of these investigations have determined how marine consumers sense and respond to these natural products (Derby, 2007). Even less understood is how these natural products affect a consumer's ability to learn and remember in predator-prey interactions (Lindquist and Hay, 1995;Long and Hay, 2006), and ultimately how resultant behavioral changes can impact the ecology of the organism. To stimulate further research on these topics, in this section we provide neuroecological examples that relate to the natural products we have discussed.…”

Section: Consumer Neuroecologymentioning

confidence: 99%

Chemical Defenses: From Compounds to Communities

Paul

Arthur

Ritson‐Williams

et al. 2007

The Biological Bulletin

180

152

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“…Polygodial is also found in ferns (pteridophytes), bryophytes (liverworts) (13,14), and even in animals. Studies on Mediterranean and Pacific sea slugs have shown that these animals synthesize polygodial as a chemodefensive agent to deter predatory fish (15,16). Thus, pungent sesquiterpenes are used as chemical defense agents across plant, fungal, and animal kingdoms.…”

mentioning

confidence: 99%

TRPA1 Mediates the Noxious Effects of Natural Sesquiterpene Deterrents

Escalera¹,

Hehn²,

Bessac

et al. 2008

Journal of Biological Chemistry

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Plants, fungi, and animals generate a diverse array of deterrent natural products that induce avoidance behavior in biological adversaries. The largest known chemical family of deterrents are terpenes characterized by reactive ␣,␤-unsaturated dialdehyde moieties, including the drimane sesquiterpenes and other terpene species. Deterrent sesquiterpenes are potent activators of mammalian peripheral chemosensory neurons, causing pain and neurogenic inflammation. Despite their widespread synthesis and medicinal use as desensitizing analgesics, their molecular targets remain unknown. Here we show that isovelleral, a noxious fungal sesquiterpene, excites sensory neurons through activation of TPRA1, an ion channel involved in inflammatory pain signaling. TRPA1 is also activated by polygodial, a drimane sesquiterpene synthesized by plants and animals. TRPA1-deficient mice show greatly reduced nocifensive behavior in response to isovelleral, indicating that TRPA1 is the major receptor for deterrent sesquiterpenes in vivo. Isovelleral and polygodial represent the first fungal and animal small molecule agonists of nociceptive transient receptor potential channels.Terpenes represent the largest group of natural products synthesized by plants, fungi, animals, and microorganisms (1). Although some terpenes function as hormonal messengers or as constituents of biological membranes and enzymatic cofactors, the biological functions of most of the ϳ25,000 different terpenes remain to be determined (1). Recent studies investigating the biochemical interactions of plants, fungi, and animals suggest that one of the major biological roles of terpenes is to act as chemical deterrents against herbivores, fungivores, and predators, respectively (1, 2). Deterrent terpenes interact with chemosensory detection systems in target organisms to induce avoidance behavior. In animals, it has been speculated that chemodefensive terpenes could activate gustatory and olfactory pathways as well as pain-sensing neuronal pathways. Indeed, some terpenes produce a painfully pungent taste in humans, probably related to their deterrent function.Recent research on terpene deterrents has focused on sesquiterpenes, a class of terpenes consisting of three isoprene units. One of the most intensively studied defensive sesquiterpenes is isovelleral, the pungent product of the fungus Lactarius vellereus. Isovelleral is thought to be part of a fungal chemical defense system against predators (3, 4) and is rapidly synthesized in response to injury from chemical precursors stored in the fungal laticiferous hyphae (5, 6). In behavioral tests, fungivorous mammals were strongly repelled by isovelleral (5, 6). In humans, skin contact with the fungal milky exudate often leads to painful inflammatory responses, including eczema and blistering (7,8). Another pungent sesquiterpene is polygodial, initially isolated from the leaves of water pepper (Polygonum hydropiper) (9). Polygodial is also a major product of winter's bark (Drimys winteri), a South American medicinal tree, ...

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Fishes learn aversions to a nudibranchs chemical defense

Cited by 39 publications

References 58 publications

Escape by Inking and Secreting: Marine Molluscs Avoid Predators Through a Rich Array of Chemicals and Mechanisms

Escape by Inking and Secreting: Marine Molluscs Avoid Predators Through a Rich Array of Chemicals and Mechanisms

Chemical Defenses: From Compounds to Communities

TRPA1 Mediates the Noxious Effects of Natural Sesquiterpene Deterrents

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Fishes learn aversions to a nudibranchs chemical defense

Cited by 39 publications

References 58 publications

Escape by Inking and Secreting: Marine Molluscs Avoid Predators Through a Rich Array of Chemicals and Mechanisms

Escape by Inking and Secreting: Marine Molluscs Avoid Predators Through a Rich Array of Chemicals and Mechanisms

Chemical Defenses: From Compounds to Communities

TRPA1 Mediates the Noxious Effects of Natural Sesquiterpene Deterrents

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Product

Resources

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Fishes learn aversions to a nudibranchs chemical defense