Predators usurp prey defenses? Toxicokinetics of tetrodotoxin in common garter snakes after consumption of rough-skinned newts

Snakes are common predators of organisms, such as amphibians, with toxic defenses that can be lethal to other predators. Because snakes do not have the option of dissecting prey into edible versus inedible components, they face a full dose of any chemical defenses encountered during attempted predat...

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Bibliographic Details
Published in:Chemoecology 2012-09, Vol.22 (3), p.179-185
Main Authors: Williams, Becky L, Hanifin, Charles T, Brodie, Edmund D., Jr, Brodie, Edmund D., III
Format: Article
Language:English
Subjects:
bioaccumulation
Biomedical and Life Sciences
Ecology
Entomology
evolution
half life
Life Sciences
liver
Nature Conservation
oral administration
pharmacokinetics
poisoning
predation
predators
Research Paper
salamanders and newts
Salamandridae
snakes
Taricha granulosa
tetrodotoxin
Thamnophis
Thamnophis sirtalis
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Summary:Snakes are common predators of organisms, such as amphibians, with toxic defenses that can be lethal to other predators. Because snakes do not have the option of dissecting prey into edible versus inedible components, they face a full dose of any chemical defenses encountered during attempted predation. This limitation has likely resulted in intense selection favoring the evolution of alternative mechanisms for dealing with prey toxins. These mechanisms can be physiological (e.g., resistance to prey toxins) or behavioral (e.g., toxin sampling and rejection). When physiological resistance arises, the possibility of bioaccumulation of a toxin results. We examined the coevolutionary interaction between the common garter snake (Thamnophis sirtalis) and the rough-skinned newt (Taricha granulosa), which contains a powerful neurotoxin called tetrodotoxin (TTX). In some populations syntopic with newts, individuals of T. sirtalis have evolved resistance to TTX. We examined the persistence of TTX in T. sirtalis after administration of an oral dose of TTX to investigate the possibility that snakes are sequestering TTX. The half-life of TTX in snake liver was estimated at 8.1 days. Accordingly, clearance of 99% of a single dose of TTX averages 61 days. Negative fitness consequences of intoxication during and after newt consumption may be balanced by co-opting the newts’ chemical defense for protection from the snakes’ own predators. Accounting of the coevolutionary dynamic between snakes and newts must incorporate post-consumption affects of lingering TTX.
ISSN:0937-7409
1423-0445
DOI:10.1007/s00049-011-0093-3