2012, ISBN 0309265355, xvi, 134
The goal of the U.S. Department of Defense's (DoD's) Chemical and Biological Defense Program (CBDP) is to provide support and world-class capabilities enabling...
Prevention | Chemical weapons | Biological weapons | Terrorism | Defense measures | Chemical arms control | Biological arms control
Prevention | Chemical weapons | Biological weapons | Terrorism | Defense measures | Chemical arms control | Biological arms control
Book
2003, ISBN 0833034502, xxi, 77
Book
Journal of Ecology, ISSN 0022-0477, 01/2017, Volume 105, Issue 1, pp. 255 - 264
Summary The success of invasive plants has often been attributed to their rapid evolution at the introduced range. In particular, release from native enemies...
chemical defence | Impatiens glandulifera | Urtica dioica | allelopathy | naphthoquinone | Deilephila elpenor | evolution of increased competitive ability | novel weapons hypothesis | invasion ecology | HERBIVORY | BIOLOGICAL INVASIONS | SUCCESS | POPULATIONS | TIME | PLANT SCIENCES | IMPACT | HYPOTHESIS | SPECIES RICHNESS | ECOLOGY | IMPATIENS-GLANDULIFERA ROYLE | INCREASED COMPETITIVE ABILITY | Evolution | Defense industry | Plants | Gardens | Evolutionary biology | Analysis | Allelopathy | Herbivores | Plant resistance | Nonnative species
chemical defence | Impatiens glandulifera | Urtica dioica | allelopathy | naphthoquinone | Deilephila elpenor | evolution of increased competitive ability | novel weapons hypothesis | invasion ecology | HERBIVORY | BIOLOGICAL INVASIONS | SUCCESS | POPULATIONS | TIME | PLANT SCIENCES | IMPACT | HYPOTHESIS | SPECIES RICHNESS | ECOLOGY | IMPATIENS-GLANDULIFERA ROYLE | INCREASED COMPETITIVE ABILITY | Evolution | Defense industry | Plants | Gardens | Evolutionary biology | Analysis | Allelopathy | Herbivores | Plant resistance | Nonnative species
Journal Article
2001, ISBN 9780815700081, xii, 258
Book
2007, ISBN 9780754648567, 214
Why are some military organizations more adept than others at reinventing themselves? Why do some efforts succeed rapidly while others only gather momentum...
History | United States Armed ForcesReorganizationHistory | Strategy | Interdisciplinary studies | Military & Naval History | Security Studies - Pol & Intl Relns | War & Conflict Studies | Case studies | 20th century | Armed Forces | United States | Reorganization
History | United States Armed ForcesReorganizationHistory | Strategy | Interdisciplinary studies | Military & Naval History | Security Studies - Pol & Intl Relns | War & Conflict Studies | Case studies | 20th century | Armed Forces | United States | Reorganization
Book
2011, ISBN 9780160893360
Interagency coordination | Terrorism | Finance | Bioterrorism | Chemical arms control | Biological arms control | Government policy | Weapons of mass destruction | Prevention | United States. Defense Threat Reduction Agency Appropriations and expenditures | Chemical and Biological Defense Program (U.S.) Appropriations and expenditures | Nuclear nonproliferation | Biosecurity
eBook
Ecology, ISSN 0012-9658, 7/2006, Volume 87, Issue 7, pp. S132 - S166
Given that a plant's defensive strategy against herbivory is never likely to be a single trait, we develop the concept of plant defense syndromes, where...
Biological taxonomies | Ecological genetics | Phylogenetics | Evolution | Trichomes | Plants | Herbivores | Phylogeny | Latex | Phenotypic traits | cardenolides | chemical ecology | Asclepias | latex | plant–insect interactions | phylogenetically independent contrasts | Danaus plexippus | coevolution | herbivory | monarch butterfly | cluster analysis | milkweed | phytochemistry | Cluster analysis | Monarch butterfly | Milkweed | Herbivory | Chemical ecology | Coevolution | Phylogenetically independent contrasts | Plant-insect interactions | Phytochemistry | Cardenolides | ANTIHERBIVORE DEFENSES | LIKELIHOOD APPROACH | MONARCH BUTTERFLIES | PHYLOGENETIC INFERENCE | MILKWEED ASCLEPIAS-SYRIACA | COMMON MILKWEED | HUMMINGBIRD POLLINATION | plant-insect interactions | SPECIALIST HERBIVORE | ECOLOGY | TRADE-OFFS | SAXIFRAGALES ANGIOSPERMS | Asclepias - classification | Data Interpretation, Statistical | Animals | Larva | Cardenolides - metabolism | Ecosystem | Latex - metabolism | Asclepias - physiology | Butterflies | Plant Leaves - physiology | Plant defenses | Research
Biological taxonomies | Ecological genetics | Phylogenetics | Evolution | Trichomes | Plants | Herbivores | Phylogeny | Latex | Phenotypic traits | cardenolides | chemical ecology | Asclepias | latex | plant–insect interactions | phylogenetically independent contrasts | Danaus plexippus | coevolution | herbivory | monarch butterfly | cluster analysis | milkweed | phytochemistry | Cluster analysis | Monarch butterfly | Milkweed | Herbivory | Chemical ecology | Coevolution | Phylogenetically independent contrasts | Plant-insect interactions | Phytochemistry | Cardenolides | ANTIHERBIVORE DEFENSES | LIKELIHOOD APPROACH | MONARCH BUTTERFLIES | PHYLOGENETIC INFERENCE | MILKWEED ASCLEPIAS-SYRIACA | COMMON MILKWEED | HUMMINGBIRD POLLINATION | plant-insect interactions | SPECIALIST HERBIVORE | ECOLOGY | TRADE-OFFS | SAXIFRAGALES ANGIOSPERMS | Asclepias - classification | Data Interpretation, Statistical | Animals | Larva | Cardenolides - metabolism | Ecosystem | Latex - metabolism | Asclepias - physiology | Butterflies | Plant Leaves - physiology | Plant defenses | Research
Journal Article
1999
eBook
1998, ISBN 9780275962432, xxii, 236 p., [14] p. of plates
Book
1998
eBook
1999, Testimony, Volume GAO/T-NSIAD-00-49.
eBook
Biological Reviews, ISSN 1464-7931, 08/2014, Volume 89, Issue 3, pp. 531 - 551
ABSTRACT Insect herbivory is often restricted by glucosylated plant chemical defence compounds that are activated by plant β‐glucosidases to release toxic...
feeding guild | insect adaptations | insect herbivore‐plant interactions | sequestration | generalists and specialists | β‐glucosidases | β‐glucosides | gut pH | two‐component plant chemical defence | Feeding guild | Two-component plant chemical defence | Insect herbivore-plant interactions | Generalists and specialists | Insect adaptations | Sequestration | Gut pH | β-glucosides | β-glucosidases | BACILLUS-THURINGIENSIS | SPODOPTERA-FRUGIPERDA | GENERALIST INSECT | SCHISTOCERCA-GREGARIA | beta-glucosides | MIDGUT PH | beta-glucosidases | BIOLOGY | CYANOGENIC GLYCOSIDES | insect herbivore-plant interactions | two-component plant chemical defence | MACULATUS F COLEOPTERA | SPECIALIST HERBIVORES | PHENOLIC GLYCOSIDES | ADAPTIVE SIGNIFICANCE | Alkaloids - toxicity | Glucosides - toxicity | Herbivory - physiology | Adaptation, Physiological - physiology | Plants - enzymology | Animals | Cellulases - metabolism | Larva | Glucosides - chemistry | Insecta - physiology | Molecular Structure | Plants - chemistry | Alkaloids - chemistry | Benzoxazines - toxicity | Benzoxazines - chemistry | Insects | Physiological aspects | Research
feeding guild | insect adaptations | insect herbivore‐plant interactions | sequestration | generalists and specialists | β‐glucosidases | β‐glucosides | gut pH | two‐component plant chemical defence | Feeding guild | Two-component plant chemical defence | Insect herbivore-plant interactions | Generalists and specialists | Insect adaptations | Sequestration | Gut pH | β-glucosides | β-glucosidases | BACILLUS-THURINGIENSIS | SPODOPTERA-FRUGIPERDA | GENERALIST INSECT | SCHISTOCERCA-GREGARIA | beta-glucosides | MIDGUT PH | beta-glucosidases | BIOLOGY | CYANOGENIC GLYCOSIDES | insect herbivore-plant interactions | two-component plant chemical defence | MACULATUS F COLEOPTERA | SPECIALIST HERBIVORES | PHENOLIC GLYCOSIDES | ADAPTIVE SIGNIFICANCE | Alkaloids - toxicity | Glucosides - toxicity | Herbivory - physiology | Adaptation, Physiological - physiology | Plants - enzymology | Animals | Cellulases - metabolism | Larva | Glucosides - chemistry | Insecta - physiology | Molecular Structure | Plants - chemistry | Alkaloids - chemistry | Benzoxazines - toxicity | Benzoxazines - chemistry | Insects | Physiological aspects | Research
Journal Article
The New Phytologist, ISSN 0028-646X, 4/2008, Volume 178, Issue 1, pp. 41 - 61
Many plants interact with carnivores as an indirect defence against herbivores. The release of volatile organic compounds (VOCs) and the secretion of...
Volatile organic compounds | Nectar | Ants | Tansley review | Nectaries | Plants | Herbivores | Insect ecology | Phytophagous insects | Chemical ecology | Infestation | parasitoid | ant–plant interactions | induced resistance | extrafloral nectar | crop protection | induced defence | plant–animal interactions | signalling | Extrafloral nectar | Ant-plant interactions | Induced defence | Parasitoid | Crop protection | Induced resistance | Signalling | Plant-animal interactions | EXTRA-FLORAL NECTARIES | INDUCED PLANT VOLATILES | JASMONATE-REGULATED DEFENSE | BEAN PHASEOLUS-LUNATUS | HERBIVORE-INDUCED VOLATILES | PLANT SCIENCES | FOOD BODY PRODUCTION | plant-animal interactions | ant-plant interactions | EXTRAFLORAL NECTAR PRODUCTION | ANT-PLANT | OCTADECANOID-SIGNALING PATHWAY | LEAF DOMATIA | Insecta - physiology | Plants - metabolism | Animals | Ecosystem | Feeding Behavior - physiology | Symbiosis - physiology
Volatile organic compounds | Nectar | Ants | Tansley review | Nectaries | Plants | Herbivores | Insect ecology | Phytophagous insects | Chemical ecology | Infestation | parasitoid | ant–plant interactions | induced resistance | extrafloral nectar | crop protection | induced defence | plant–animal interactions | signalling | Extrafloral nectar | Ant-plant interactions | Induced defence | Parasitoid | Crop protection | Induced resistance | Signalling | Plant-animal interactions | EXTRA-FLORAL NECTARIES | INDUCED PLANT VOLATILES | JASMONATE-REGULATED DEFENSE | BEAN PHASEOLUS-LUNATUS | HERBIVORE-INDUCED VOLATILES | PLANT SCIENCES | FOOD BODY PRODUCTION | plant-animal interactions | ant-plant interactions | EXTRAFLORAL NECTAR PRODUCTION | ANT-PLANT | OCTADECANOID-SIGNALING PATHWAY | LEAF DOMATIA | Insecta - physiology | Plants - metabolism | Animals | Ecosystem | Feeding Behavior - physiology | Symbiosis - physiology
Journal Article