Herbivore physiological response to predation risk and implications for ecosystem nutrient dynamics

The process of nutrient transfer through an ecosystem is an important determinant of production, food-chain length, and species diversity. The general view is that the rate and efficiency of nutrient transfer up the food chain is constrained by herbivore-specific capacity to secure N-rich compounds...

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Veröffentlicht in:	Proceedings of the National Academy of Sciences - PNAS 2010-08, Vol.107 (35), p.15503-15507
Hauptverfasser:	Hawlena, Dror, Schmitz, Oswald J.
Format:	Artikel
Sprache:	eng
Schlagworte:	Analysis of Variance Animal Feed Animal Nutritional Physiological Phenomena - physiology Animals Araneae Biodiversity Biological Sciences Carbohydrates Carbon - metabolism Diet Diets Ecology Ecosystem Ecosystems Fecal coliforms Feeding trials Food Food Chain Food chains Grasses Grasshoppers - metabolism Grasshoppers - physiology Herbivores Insects Metabolic rate Metabolism Nitrogen - metabolism Nutrient dynamics Nutrient intake Nutrient requirements Nutrients Physiological responses Physiology Plant communities Plants Plants - classification Plants - metabolism Plants - parasitology Population Dynamics Predation Predators Predatory Behavior - physiology Risk Factors Species diversity Spiders - physiology Survival Terrestrial ecosystems Tissues
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container_end_page	15507
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container_start_page	15503
container_title	Proceedings of the National Academy of Sciences - PNAS
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creator	Hawlena, Dror Schmitz, Oswald J.
description	The process of nutrient transfer through an ecosystem is an important determinant of production, food-chain length, and species diversity. The general view is that the rate and efficiency of nutrient transfer up the food chain is constrained by herbivore-specific capacity to secure N-rich compounds for survival and production. Using feeding trials with artificial food, we show, however, that physiological stress-response of grasshopper herbivores to spider predation risk alters the nature of the nutrient constraint. Grasshoppers facing predation risk had higher metabolic rates than control grasshoppers. Elevated metabolism accordingly increased requirements for dietary digestible carbohydrate-C to fuel-heightened energy demands. Moreover, digestible carbohydrate-C comprises a small fraction of total plant tissue-C content, so nutrient transfer between plants and herbivores accordingly becomes more constrained by digestible plant C than by total plant C:N. This shift in herbivore diet to meet the altered nutrient requirement increased herbivore body C:N content, the C:N content of the plant community from which grasshoppers select their diet, and grasshopper fecal C:N content. Chronic predation risk thus alters the quality of animal and plant tissue that eventually enters the detrital pool to become decomposed. Our results demonstrate that herbivore physiology causes C:N requirements and nutrient intake to become flexible, thereby providing a mechanism to explain context dependence in the nature of trophic control over nutrient transfer in ecosystems.
doi_str_mv	10.1073/pnas.1009300107
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This shift in herbivore diet to meet the altered nutrient requirement increased herbivore body C:N content, the C:N content of the plant community from which grasshoppers select their diet, and grasshopper fecal C:N content. Chronic predation risk thus alters the quality of animal and plant tissue that eventually enters the detrital pool to become decomposed. 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This shift in herbivore diet to meet the altered nutrient requirement increased herbivore body C:N content, the C:N content of the plant community from which grasshoppers select their diet, and grasshopper fecal C:N content. Chronic predation risk thus alters the quality of animal and plant tissue that eventually enters the detrital pool to become decomposed. 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This shift in herbivore diet to meet the altered nutrient requirement increased herbivore body C:N content, the C:N content of the plant community from which grasshoppers select their diet, and grasshopper fecal C:N content. Chronic predation risk thus alters the quality of animal and plant tissue that eventually enters the detrital pool to become decomposed. Our results demonstrate that herbivore physiology causes C:N requirements and nutrient intake to become flexible, thereby providing a mechanism to explain context dependence in the nature of trophic control over nutrient transfer in ecosystems.</abstract><cop>United States</cop><pub>National Academy of Sciences</pub><pmid>20713698</pmid><doi>10.1073/pnas.1009300107</doi><tpages>5</tpages><oa>free_for_read</oa></addata></record>
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subjects	Analysis of Variance Animal Feed Animal Nutritional Physiological Phenomena - physiology Animals Araneae Biodiversity Biological Sciences Carbohydrates Carbon - metabolism Diet Diets Ecology Ecosystem Ecosystems Fecal coliforms Feeding trials Food Food Chain Food chains Grasses Grasshoppers - metabolism Grasshoppers - physiology Herbivores Insects Metabolic rate Metabolism Nitrogen - metabolism Nutrient dynamics Nutrient intake Nutrient requirements Nutrients Physiological responses Physiology Plant communities Plants Plants - classification Plants - metabolism Plants - parasitology Population Dynamics Predation Predators Predatory Behavior - physiology Risk Factors Species diversity Spiders - physiology Survival Terrestrial ecosystems Tissues
title	Herbivore physiological response to predation risk and implications for ecosystem nutrient dynamics
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