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Publication DateNature, ISSN 0028-0836, 03/2013, Volume 495, Issue 7439, pp. 134 - 134
Odd, to find such a rounded stone so far from the river. Medea did love how her new clothes fit - softas otterette skin, though strange in how they covered her...
Herbivores
Herbivores
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Loading RightsNature, ISSN 0028-0836, 07/2012, Volume 487, Issue 7405, pp. 46 - 47
[...]models of assemblage structure that are based on the concept of niche differentiation - an ecological process in which different species partition...
Herbivores
Herbivores
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Loading Rights1979, xiii, 718 p. ill.
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Journal of Ecology, ISSN 0022-0477, 1/2011, Volume 99, Issue 1, pp. 26 - 35
1. Indirect plant defences are well documented for the above-ground constituents of plants. Although less investigated to date, below-ground defences that...
Plant parasitic nematodes | Special Feature Papers | Foraging | Plant roots | Plant ecology | Nematodes | Nematode larvae | Plants | Herbivores | Chemical ecology | Human ecology | pregeijerene | Diaprepes abbreviatus | entomopathogenic nematodes | chemical ecology | herbivoreāinduced plant volatiles | plantāherbivore interactions | biological control | aboveāgroundābelowāground interactions | Herbivore-induced plant volatiles | Plant-herbivore interactions | Pregeijerene | Biological control | Above-ground-below-ground interactions | Entomopathogenic nematodes | BELOW-GROUND HERBIVORY | INSECT HERBIVORES | ROOT WEEVILS COLEOPTERA | HERBIVORE-INDUCED VOLATILES | DIAPREPES-ABBREVIATUS COLEOPTERA | PLANT SCIENCES | plant-herbivore interactions | FLORIDA CITRUS | herbivore-induced plant volatiles | INDIRECT DEFENSE | ECOLOGY | HOST-FINDING ABILITY | ECOLOGICAL COSTS | TRITROPHIC INTERACTIONS | above-ground-below-ground interactions | Parenting | School facilities | Analysis | Pests | Nematoda | Agricultural pests | Education parks
Plant parasitic nematodes | Special Feature Papers | Foraging | Plant roots | Plant ecology | Nematodes | Nematode larvae | Plants | Herbivores | Chemical ecology | Human ecology | pregeijerene | Diaprepes abbreviatus | entomopathogenic nematodes | chemical ecology | herbivoreāinduced plant volatiles | plantāherbivore interactions | biological control | aboveāgroundābelowāground interactions | Herbivore-induced plant volatiles | Plant-herbivore interactions | Pregeijerene | Biological control | Above-ground-below-ground interactions | Entomopathogenic nematodes | BELOW-GROUND HERBIVORY | INSECT HERBIVORES | ROOT WEEVILS COLEOPTERA | HERBIVORE-INDUCED VOLATILES | DIAPREPES-ABBREVIATUS COLEOPTERA | PLANT SCIENCES | plant-herbivore interactions | FLORIDA CITRUS | herbivore-induced plant volatiles | INDIRECT DEFENSE | ECOLOGY | HOST-FINDING ABILITY | ECOLOGICAL COSTS | TRITROPHIC INTERACTIONS | above-ground-below-ground interactions | Parenting | School facilities | Analysis | Pests | Nematoda | Agricultural pests | Education parks
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Loading Rights1985, ISBN 9780849359118, 314
OrgulĆ©s | Physiologie | Ungulates | Bioenergetics | MammifĆØres | Physiology | Herbivores | BioĆ©nergĆ©tique | Mammals
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Journal of Theoretical Biology, ISSN 0022-5193, 09/2016, Volume 404, pp. 10 - 14
Plant galls, induced by arthropods and various other organisms have an intimate relationship with host plants, and gall-inducers have limited mobility. In...
Anti-herbivore defense | Aphids | Collective mimicry | Plant-mediated herbivoreāherbivore interactions | Resource sink | Plant-mediated herbivore-herbivore interactions | Plant-mediated herbivore herbivore interactions | MANIPULATION | APHID | WASP | PREY | CANNIBALISM | PARASITOIDS | BIOLOGY | MATHEMATICAL & COMPUTATIONAL BIOLOGY | BIRD PREDATION | INSECTS | LEPIDOPTERA | MORPHOLOGY | Plant Tumors - parasitology | Animals | Larva - physiology | Herbivory - physiology | Models, Biological | Biological Mimicry | Aphididae | Photosynthesis | Phytochemistry
Anti-herbivore defense | Aphids | Collective mimicry | Plant-mediated herbivoreāherbivore interactions | Resource sink | Plant-mediated herbivore-herbivore interactions | Plant-mediated herbivore herbivore interactions | MANIPULATION | APHID | WASP | PREY | CANNIBALISM | PARASITOIDS | BIOLOGY | MATHEMATICAL & COMPUTATIONAL BIOLOGY | BIRD PREDATION | INSECTS | LEPIDOPTERA | MORPHOLOGY | Plant Tumors - parasitology | Animals | Larva - physiology | Herbivory - physiology | Models, Biological | Biological Mimicry | Aphididae | Photosynthesis | Phytochemistry
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Loading RightsEcology, ISSN 0012-9658, 11/2015, Volume 96, Issue 11, pp. 2923 - 2934
Herbivores are important drivers of plant species coexistence and community assembly. However, detailed mechanistic information on how herbivores affect...
growth-rate hypothesis | generalist herbivores | plant coexistence | growth-defense trade-off | herbivore performance | biotic factors | plant resistance | herbivore preference | leaf traits | Grasslands | Synecology | Plant ecology | Caterpillars | Plant communities | Herbivores | Plants | Insect ecology | Slugs | Species | growthādefense trade-off | Biotic factors | Generalist herbivores | Growth-defense trade-off | Leaf traits | Plant resistance | Herbivore performance | Plant coexistence | Growth-rate hypothesis | Herbivore preference | SPECIES-DIVERSITY | DEFENSE | INSECT HERBIVORES | INVERTEBRATE HERBIVORY | PHYTOPHAGOUS INSECTS | TRADE-OFF | TROPICAL FORESTS | INDUCED RESISTANCE | NATURAL ENEMIES | ECOLOGY | Grassland | Gastropoda - physiology | Animals | Spodoptera - physiology | Plants - genetics | Species Specificity | Herbivory - physiology | Larva - physiology | Phylogeny | Plants - classification | Plant Leaves - physiology | Grassland ecology | Research | Ecological research | Insect-plant relationships
growth-rate hypothesis | generalist herbivores | plant coexistence | growth-defense trade-off | herbivore performance | biotic factors | plant resistance | herbivore preference | leaf traits | Grasslands | Synecology | Plant ecology | Caterpillars | Plant communities | Herbivores | Plants | Insect ecology | Slugs | Species | growthādefense trade-off | Biotic factors | Generalist herbivores | Growth-defense trade-off | Leaf traits | Plant resistance | Herbivore performance | Plant coexistence | Growth-rate hypothesis | Herbivore preference | SPECIES-DIVERSITY | DEFENSE | INSECT HERBIVORES | INVERTEBRATE HERBIVORY | PHYTOPHAGOUS INSECTS | TRADE-OFF | TROPICAL FORESTS | INDUCED RESISTANCE | NATURAL ENEMIES | ECOLOGY | Grassland | Gastropoda - physiology | Animals | Spodoptera - physiology | Plants - genetics | Species Specificity | Herbivory - physiology | Larva - physiology | Phylogeny | Plants - classification | Plant Leaves - physiology | Grassland ecology | Research | Ecological research | Insect-plant relationships
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Loading RightsEcology and Evolution, ISSN 2045-7758, 08/2012, Volume 2, Issue 8, pp. 1818 - 1825
Environmental gradients have been postulated to generate patterns of diversity and diet specialization, in which more stable environments, such as tropical...
generalist herbivores | phylogenetic ecology | Diet breadth | polyphagy | host plant | plant resistance | specialist herbivores | plantāherbivore interaction | Generalist herbivores | Polyphagy | Plant-herbivore interaction | Host plant | Plant resistance | Phylogenetic ecology | Specialist herbivores | HOST-SPECIFICITY | TEMPERATE | FOLIAR CHEMISTRY | SUITABILITY | TROPICAL FORESTS | COMMUNITY | plant-herbivore interaction | BUTTERFLIES | INSECTS | ECOLOGY | DIVERSITY | LEPIDOPTERA | Taxonomy | Phylogeny | Biodiversity | Defense | Butterflies | Biological diversity | Studies | Specialization | Hypotheses | Elevation | Plant diversity | Diet | Host plants | Tropical environment | Alpine regions | Phylogenetics | Butterflies & moths | Tropical environments | Herbivores | Species richness | Environmental gradient | Original Research
generalist herbivores | phylogenetic ecology | Diet breadth | polyphagy | host plant | plant resistance | specialist herbivores | plantāherbivore interaction | Generalist herbivores | Polyphagy | Plant-herbivore interaction | Host plant | Plant resistance | Phylogenetic ecology | Specialist herbivores | HOST-SPECIFICITY | TEMPERATE | FOLIAR CHEMISTRY | SUITABILITY | TROPICAL FORESTS | COMMUNITY | plant-herbivore interaction | BUTTERFLIES | INSECTS | ECOLOGY | DIVERSITY | LEPIDOPTERA | Taxonomy | Phylogeny | Biodiversity | Defense | Butterflies | Biological diversity | Studies | Specialization | Hypotheses | Elevation | Plant diversity | Diet | Host plants | Tropical environment | Alpine regions | Phylogenetics | Butterflies & moths | Tropical environments | Herbivores | Species richness | Environmental gradient | Original Research
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Loading RightsBiogeochemistry, ISSN 0168-2563, 11/2012, Volume 111, Issue 1/3, pp. 1 - 39
C, N and P are three of the most important elements used to build living beings, and their uptake from the environment is consequently essential for all...
Stoichiometry | Terrestrial ecosystems | Marine ecology | SYNTHESIS AND EMERGING IDEAS | Marine ecosystems | Phosphorus | Plants | Freshwater ecosystems | Nitrogen | Species | Soil ecology | Competition | Earth Sciences | Biogeosciences | Life Sciences, general | Ecosystems | Diversity | Climate gradients | Herbivoreāpredator | Plantāherbivore | Redfieldās ratio | Environmental Chemistry | Redfield's ratio | Herbivore-predator | Plant-herbivore | ECOLOGICAL STOICHIOMETRY | FOOD-WEB STRUCTURE | PRODUCER-GRAZER SYSTEMS | N-P STOICHIOMETRY | GROWTH-RATE | NUTRIENT LIMITATION | PHOSPHORUS STOICHIOMETRY | FRESH-WATER | PREDATOR-PREY INTERACTIONS | ENVIRONMENTAL SCIENCES | GEOSCIENCES, MULTIDISCIPLINARY | NITROGEN LIMITATION | Physiological aspects | Environmental aspects | Ecosystem components | Genomics | Herbivores | Predation | Aquatic ecosystems
Stoichiometry | Terrestrial ecosystems | Marine ecology | SYNTHESIS AND EMERGING IDEAS | Marine ecosystems | Phosphorus | Plants | Freshwater ecosystems | Nitrogen | Species | Soil ecology | Competition | Earth Sciences | Biogeosciences | Life Sciences, general | Ecosystems | Diversity | Climate gradients | Herbivoreāpredator | Plantāherbivore | Redfieldās ratio | Environmental Chemistry | Redfield's ratio | Herbivore-predator | Plant-herbivore | ECOLOGICAL STOICHIOMETRY | FOOD-WEB STRUCTURE | PRODUCER-GRAZER SYSTEMS | N-P STOICHIOMETRY | GROWTH-RATE | NUTRIENT LIMITATION | PHOSPHORUS STOICHIOMETRY | FRESH-WATER | PREDATOR-PREY INTERACTIONS | ENVIRONMENTAL SCIENCES | GEOSCIENCES, MULTIDISCIPLINARY | NITROGEN LIMITATION | Physiological aspects | Environmental aspects | Ecosystem components | Genomics | Herbivores | Predation | Aquatic ecosystems
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Loading RightsJournal of Ecology, ISSN 0022-0477, 05/2017, Volume 105, Issue 3, pp. 674 - 686
Summary Productivity and herbivory often interact to shape plant community composition and species richness with levels of production mediating the impact of...
foundation species | abiotic gradients | plant dominance | plantāherbivore interactions | megaāherbivore | mesoāherbivore | topādown effects | bottomāup effects | grazing lawn | wildlife decline | bottom-up effects | mega-herbivore | top-down effects | meso-herbivore | TALLGRASS PRAIRIE | SOUTH-AFRICAN | COMPETITIVE ABILITY | PLANT SCIENCES | plant-herbivore interactions | GRASSLAND PLANT DIVERSITY | COMMUNITY STRUCTURE | FIRE FREQUENCY | SEMIARID RANGELAND | SPECIES RICHNESS | ECOLOGY | NORTH-AMERICAN | KRUGER-NATIONAL-PARK
foundation species | abiotic gradients | plant dominance | plantāherbivore interactions | megaāherbivore | mesoāherbivore | topādown effects | bottomāup effects | grazing lawn | wildlife decline | bottom-up effects | mega-herbivore | top-down effects | meso-herbivore | TALLGRASS PRAIRIE | SOUTH-AFRICAN | COMPETITIVE ABILITY | PLANT SCIENCES | plant-herbivore interactions | GRASSLAND PLANT DIVERSITY | COMMUNITY STRUCTURE | FIRE FREQUENCY | SEMIARID RANGELAND | SPECIES RICHNESS | ECOLOGY | NORTH-AMERICAN | KRUGER-NATIONAL-PARK
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Loading RightsEcology, ISSN 0012-9658, 08/2018, Volume 99, Issue 8, pp. 1866 - 1877
Soil type is understudied as a driver of herbivore community size and structure across host plants. This study extends predictions of resource availability...
resource availability hypotheses | plantāherbivore interaction | herbivore diversity | plant resistance | serpentine soil | herbivore abundance | plant-herbivore interaction | INSECT HERBIVORES | PERFORMANCE | RESOURCE AVAILABILITY | ELEMENTAL DEFENSE | BIOMECHANICAL PROPERTIES | NATURAL ENEMIES | PLANT DEFENSE | HYPOTHESIS | NITROGEN | ECOLOGY | TRITROPHIC INTERACTIONS | Chaparral ecology | Plant-soil relationships | Plant defenses | Research | Ecological research | Insect-plant relationships | Soil resistance | Soils | Chaparral | Communities | Host plants | Soil types | Plant resistance | Resource availability | Herbivores
resource availability hypotheses | plantāherbivore interaction | herbivore diversity | plant resistance | serpentine soil | herbivore abundance | plant-herbivore interaction | INSECT HERBIVORES | PERFORMANCE | RESOURCE AVAILABILITY | ELEMENTAL DEFENSE | BIOMECHANICAL PROPERTIES | NATURAL ENEMIES | PLANT DEFENSE | HYPOTHESIS | NITROGEN | ECOLOGY | TRITROPHIC INTERACTIONS | Chaparral ecology | Plant-soil relationships | Plant defenses | Research | Ecological research | Insect-plant relationships | Soil resistance | Soils | Chaparral | Communities | Host plants | Soil types | Plant resistance | Resource availability | Herbivores
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