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INDUCIBLE DEFENSES IN MULTIPREDATOR ENVIRONMENTS: CYCLOMORPHOSIS IN DAPHNIA CUCULLATA.

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INDUCIBLE DEFENSES IN MULTIPREDATOR ENVIRONMENTS: CYCLOMORPHOSIS IN DAPHNIA CUCULLATA. / Laforsch, Christian; Tollrian, Ralph.
In: Ecology, Vol. 85, No. 8, 08.2004, p. 2302-2311.

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Laforsch C, Tollrian R. INDUCIBLE DEFENSES IN MULTIPREDATOR ENVIRONMENTS: CYCLOMORPHOSIS IN DAPHNIA CUCULLATA. Ecology. 2004 Aug;85(8):2302-2311. doi: 10.1890/03-0286

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Laforsch, Christian ; Tollrian, Ralph. / INDUCIBLE DEFENSES IN MULTIPREDATOR ENVIRONMENTS: CYCLOMORPHOSIS IN DAPHNIA CUCULLATA. In: Ecology. 2004 ; Vol. 85, No. 8. pp. 2302-2311.

Bibtex

@article{d0bd5fda88934e5894e6b5baca833d07,
title = "INDUCIBLE DEFENSES IN MULTIPREDATOR ENVIRONMENTS: CYCLOMORPHOSIS IN DAPHNIA CUCULLATA.",
abstract = "Phenotypically plastic defenses are strategies to reduce predation risk in variable environments. Predator-induced formations of protective devices in cladocerans are prominent examples of phenotypically plastic defenses. To understand the adaptive value of a defense, it is better to investigate its effects in a multipredator context, instead of merely concentrating on a two-species interaction. Small cladocerans such as Daphnia cucullata are prey items for many aquatic invertebrate predators and thus comprise a useful model system to investigate defenses and their effects. In this study, we tested the hypothesis that the helmets of Daphnia cucullata are inducible with chemical cues from different kinds of predators and that they act as a generalized defense offering protection against several predators, each using a different hunting strategy. Results from our induction experiment show that chemical cues released from Chaoborus flavicans, Leptodora kindtii, and Cyclops sp. induce significantly longer helmets and tail spines and thus act as proximate factors for cyclomorphosis in Daphnia cucullata. Our predation experiments revealed that the induced morphological changes offered protection against each of the predators tested. Interestingly, the protective mechanisms and the prey size classes which were protected differed between predator systems. Our results suggest that phenotypic plasticity in Daphnia cucullata evolved as a “diffuse” coevolution against different invertebrate predators which selectively feed on small prey items. The additive benefits may increase the adaptive value and thus facilitate the evolution and persistence of this generalized defense.",
keywords = "cyclomorphosis, diffuse coevolution, functional morphology, inducible defenses, multipredator environments, phenotypic plasticity",
author = "Christian Laforsch and Ralph Tollrian",
year = "2004",
month = aug,
doi = "10.1890/03-0286",
language = "English",
volume = "85",
pages = "2302--2311",
journal = "Ecology",
issn = "0012-9658",
publisher = "Ecological Society of America",
number = "8",

}

RIS

TY - JOUR

T1 - INDUCIBLE DEFENSES IN MULTIPREDATOR ENVIRONMENTS: CYCLOMORPHOSIS IN DAPHNIA CUCULLATA.

AU - Laforsch, Christian

AU - Tollrian, Ralph

PY - 2004/8

Y1 - 2004/8

N2 - Phenotypically plastic defenses are strategies to reduce predation risk in variable environments. Predator-induced formations of protective devices in cladocerans are prominent examples of phenotypically plastic defenses. To understand the adaptive value of a defense, it is better to investigate its effects in a multipredator context, instead of merely concentrating on a two-species interaction. Small cladocerans such as Daphnia cucullata are prey items for many aquatic invertebrate predators and thus comprise a useful model system to investigate defenses and their effects. In this study, we tested the hypothesis that the helmets of Daphnia cucullata are inducible with chemical cues from different kinds of predators and that they act as a generalized defense offering protection against several predators, each using a different hunting strategy. Results from our induction experiment show that chemical cues released from Chaoborus flavicans, Leptodora kindtii, and Cyclops sp. induce significantly longer helmets and tail spines and thus act as proximate factors for cyclomorphosis in Daphnia cucullata. Our predation experiments revealed that the induced morphological changes offered protection against each of the predators tested. Interestingly, the protective mechanisms and the prey size classes which were protected differed between predator systems. Our results suggest that phenotypic plasticity in Daphnia cucullata evolved as a “diffuse” coevolution against different invertebrate predators which selectively feed on small prey items. The additive benefits may increase the adaptive value and thus facilitate the evolution and persistence of this generalized defense.

AB - Phenotypically plastic defenses are strategies to reduce predation risk in variable environments. Predator-induced formations of protective devices in cladocerans are prominent examples of phenotypically plastic defenses. To understand the adaptive value of a defense, it is better to investigate its effects in a multipredator context, instead of merely concentrating on a two-species interaction. Small cladocerans such as Daphnia cucullata are prey items for many aquatic invertebrate predators and thus comprise a useful model system to investigate defenses and their effects. In this study, we tested the hypothesis that the helmets of Daphnia cucullata are inducible with chemical cues from different kinds of predators and that they act as a generalized defense offering protection against several predators, each using a different hunting strategy. Results from our induction experiment show that chemical cues released from Chaoborus flavicans, Leptodora kindtii, and Cyclops sp. induce significantly longer helmets and tail spines and thus act as proximate factors for cyclomorphosis in Daphnia cucullata. Our predation experiments revealed that the induced morphological changes offered protection against each of the predators tested. Interestingly, the protective mechanisms and the prey size classes which were protected differed between predator systems. Our results suggest that phenotypic plasticity in Daphnia cucullata evolved as a “diffuse” coevolution against different invertebrate predators which selectively feed on small prey items. The additive benefits may increase the adaptive value and thus facilitate the evolution and persistence of this generalized defense.

KW - cyclomorphosis

KW - diffuse coevolution

KW - functional morphology

KW - inducible defenses

KW - multipredator environments

KW - phenotypic plasticity

U2 - 10.1890/03-0286

DO - 10.1890/03-0286

M3 - Journal article

VL - 85

SP - 2302

EP - 2311

JO - Ecology

JF - Ecology

SN - 0012-9658

IS - 8

ER -