Journal of Experimental Botany, ISSN 0022-0957, 10/2016, Volume 67, Issue 19, pp. 5711 - 5723
Recent research suggests that systemic signalling and communication between roots and leaves plays an important role in plant defence against herbivores. In...
Citrus | glutamate-receptor like | glutamic acid | systemic resistance | Tetranychus urticae | grafting | DEFENSE | ABIOTIC STRESS | ACQUIRED-RESISTANCE | WOUND RESPONSE | PLANT SCIENCES | GLUTAMATE-RECEPTOR | PLANT IMMUNITY | SPIDER-MITE | ARABIDOPSIS | JASMONIC ACID | TOMATO | Plant Leaves - chemistry | Receptors, Glutamate - metabolism | Citrus - physiology | Plant Growth Regulators - physiology | Amino Acids - physiology | Glutamic Acid - physiology | Herbivory | Tetranychidae - physiology | Plant Roots - physiology | Oxylipins - metabolism | Citrus - metabolism | Animals | Plant Shoots - metabolism | Gene Expression Regulation, Plant | Cyclopentanes - metabolism | Signal Transduction - physiology | Plant Leaves - physiology | Receptors, Glutamate - physiology | Glutamic Acid - analysis | Research Paper
Citrus | glutamate-receptor like | glutamic acid | systemic resistance | Tetranychus urticae | grafting | DEFENSE | ABIOTIC STRESS | ACQUIRED-RESISTANCE | WOUND RESPONSE | PLANT SCIENCES | GLUTAMATE-RECEPTOR | PLANT IMMUNITY | SPIDER-MITE | ARABIDOPSIS | JASMONIC ACID | TOMATO | Plant Leaves - chemistry | Receptors, Glutamate - metabolism | Citrus - physiology | Plant Growth Regulators - physiology | Amino Acids - physiology | Glutamic Acid - physiology | Herbivory | Tetranychidae - physiology | Plant Roots - physiology | Oxylipins - metabolism | Citrus - metabolism | Animals | Plant Shoots - metabolism | Gene Expression Regulation, Plant | Cyclopentanes - metabolism | Signal Transduction - physiology | Plant Leaves - physiology | Receptors, Glutamate - physiology | Glutamic Acid - analysis | Research Paper
Journal Article
Proceedings of the National Academy of Sciences of the United States of America, ISSN 0027-8424, 2013, Volume 110, Issue 2, pp. E113 - E122
Plants produce a wide range of allelochemicals to defend against herbivore attack, and generalist herbivores have evolved mechanisms to avoid, sequester, or...
Xenosensors | Major facilitator superfamily | Genetic variation | Lipocalin | Transcriptome | ECOLOGICAL GENETICS | transcriptome | INSECTICIDE RESISTANCE | CRYSTAL-STRUCTURE | MULTIDISCIPLINARY SCIENCES | CROSS-RESISTANCE | genetic variation | lipocalin | xenosensors | CHEMICAL ECOLOGY | DETOXIFICATION ENZYMES | APOLIPOPROTEIN-D | HERBIVOROUS INSECTS | RANGE EVOLUTION | PHYTOPHAGOUS MITE | major facilitator superfamily | Herbivory - physiology | Adaptation, Biological - genetics | Insecticide Resistance - genetics | Molecular Sequence Data | Gene Expression Profiling | Phylogeny | Likelihood Functions | Phaseolus - parasitology | Time Factors | Microarray Analysis | Base Sequence | Multigene Family - genetics | Tetranychidae - genetics | Computational Biology | Gene Expression Regulation - physiology | Insect Proteins - genetics | Insecticide Resistance - physiology | Tetranychidae - physiology | Phaseolus - chemistry | Adaptation, Biological - physiology | Host-Pathogen Interactions | Animals | Lycopersicon esculentum - parasitology | Lycopersicon esculentum - chemistry | Models, Genetic | Lipocalins - chemistry | Toxicity Tests | Cluster Analysis | Biological Sciences | PNAS Plus
Xenosensors | Major facilitator superfamily | Genetic variation | Lipocalin | Transcriptome | ECOLOGICAL GENETICS | transcriptome | INSECTICIDE RESISTANCE | CRYSTAL-STRUCTURE | MULTIDISCIPLINARY SCIENCES | CROSS-RESISTANCE | genetic variation | lipocalin | xenosensors | CHEMICAL ECOLOGY | DETOXIFICATION ENZYMES | APOLIPOPROTEIN-D | HERBIVOROUS INSECTS | RANGE EVOLUTION | PHYTOPHAGOUS MITE | major facilitator superfamily | Herbivory - physiology | Adaptation, Biological - genetics | Insecticide Resistance - genetics | Molecular Sequence Data | Gene Expression Profiling | Phylogeny | Likelihood Functions | Phaseolus - parasitology | Time Factors | Microarray Analysis | Base Sequence | Multigene Family - genetics | Tetranychidae - genetics | Computational Biology | Gene Expression Regulation - physiology | Insect Proteins - genetics | Insecticide Resistance - physiology | Tetranychidae - physiology | Phaseolus - chemistry | Adaptation, Biological - physiology | Host-Pathogen Interactions | Animals | Lycopersicon esculentum - parasitology | Lycopersicon esculentum - chemistry | Models, Genetic | Lipocalins - chemistry | Toxicity Tests | Cluster Analysis | Biological Sciences | PNAS Plus
Journal Article
Proceedings of the National Academy of Sciences of the United States of America, ISSN 0027-8424, 2019, Volume 116, Issue 12, pp. 5588 - 5596
The thermal limit of ectotherms provides an estimate of vulnerability to climate change. It differs between contrasting microhabitats, consistent with thermal...
Extended phenotype | Plant–insect interactions | Biophysical ecology | Leaf temperature | Thermal adaptation | PHYSIOLOGY | PATHOGEN | ACARI | TOLERANCE | PERFORMANCE | MULTIDISCIPLINARY SCIENCES | thermal adaptation | leaf temperature | BODY-TEMPERATURE | GLOBAL CHANGE | biophysical ecology | extended phenotype | MICROCLIMATES | plant-insect interactions | PLANT-RESPONSES | LEAF SURFACES | Plant Transpiration | Arthropods - physiology | Temperature | Animals | Climate Change | Aphids - physiology | Thermotolerance - physiology | Hot Temperature | Tetranychidae - physiology | Microclimate | Plant Leaves - physiology | Acclimatization - physiology | Feeding behavior | Communities | Warm up | Safety margins | Feeding | Climate change | Leaves | Transpiration | Insects | Heat exchange | Temperature effects | Microhabitats | Air temperature | Phyllosphere | Heat tolerance | Microenvironments | Herbivores | Gas exchange | Biodiversity and Ecology | Environmental Sciences | Global Changes | Biological Sciences | PNAS Plus | plant–insect interactions
Extended phenotype | Plant–insect interactions | Biophysical ecology | Leaf temperature | Thermal adaptation | PHYSIOLOGY | PATHOGEN | ACARI | TOLERANCE | PERFORMANCE | MULTIDISCIPLINARY SCIENCES | thermal adaptation | leaf temperature | BODY-TEMPERATURE | GLOBAL CHANGE | biophysical ecology | extended phenotype | MICROCLIMATES | plant-insect interactions | PLANT-RESPONSES | LEAF SURFACES | Plant Transpiration | Arthropods - physiology | Temperature | Animals | Climate Change | Aphids - physiology | Thermotolerance - physiology | Hot Temperature | Tetranychidae - physiology | Microclimate | Plant Leaves - physiology | Acclimatization - physiology | Feeding behavior | Communities | Warm up | Safety margins | Feeding | Climate change | Leaves | Transpiration | Insects | Heat exchange | Temperature effects | Microhabitats | Air temperature | Phyllosphere | Heat tolerance | Microenvironments | Herbivores | Gas exchange | Biodiversity and Ecology | Environmental Sciences | Global Changes | Biological Sciences | PNAS Plus | plant–insect interactions
Journal Article
PLoS ONE, ISSN 1932-6203, 10/2011, Volume 6, Issue 10, p. e24594
A blend of volatile organic compounds (VOCs) emitted from plants induced by herbivory enables the priming of defensive responses in neighboring plants. These...
AIRBORNE SIGNALS | RESPONSES | LIMA-BEAN LEAVES | SAGEBRUSH | INDUCED RESISTANCE | BIOLOGY | ARABIDOPSIS | EMISSION | DAMAGE | PREDATORY MITE | DEFENSE GENES | Wasps - drug effects | Plants - genetics | Larva - drug effects | Plants, Genetically Modified | Moths - physiology | Female | Plant Immunity - drug effects | Zea mays - physiology | Wasps - physiology | Alkenes - analysis | Plants - immunology | Tobacco - physiology | Zea mays - drug effects | Tobacco - drug effects | Plants - drug effects | Tetranychidae - physiology | Herbivory - drug effects | Volatile Organic Compounds - pharmacology | Adaptive Immunity - drug effects | Animals | Tobacco - genetics | Fabaceae - drug effects | Tetranychidae - drug effects | Larva - physiology | Alkenes - pharmacology | Fabaceae - physiology | Moths - drug effects | Volatile organic compounds | Legumes | Genetically modified plants | Beans | Analysis | Wasps | Mimosaceae | Larvae | Wind | Seeds | Genes | Science | Mites | Maize | Transgenic plants | Immunity | Allelochemicals | Communication | Organic compounds | Corn | Pest control | Priming | Herbivory | Metabolism | Volatiles | Biological diversity | Studies | Ocimene | Tobacco | Animal behavior | Genetic engineering | Volatile compounds | Herbivores | Volatile organic compounds--VOCs | Larval development | VOCs
AIRBORNE SIGNALS | RESPONSES | LIMA-BEAN LEAVES | SAGEBRUSH | INDUCED RESISTANCE | BIOLOGY | ARABIDOPSIS | EMISSION | DAMAGE | PREDATORY MITE | DEFENSE GENES | Wasps - drug effects | Plants - genetics | Larva - drug effects | Plants, Genetically Modified | Moths - physiology | Female | Plant Immunity - drug effects | Zea mays - physiology | Wasps - physiology | Alkenes - analysis | Plants - immunology | Tobacco - physiology | Zea mays - drug effects | Tobacco - drug effects | Plants - drug effects | Tetranychidae - physiology | Herbivory - drug effects | Volatile Organic Compounds - pharmacology | Adaptive Immunity - drug effects | Animals | Tobacco - genetics | Fabaceae - drug effects | Tetranychidae - drug effects | Larva - physiology | Alkenes - pharmacology | Fabaceae - physiology | Moths - drug effects | Volatile organic compounds | Legumes | Genetically modified plants | Beans | Analysis | Wasps | Mimosaceae | Larvae | Wind | Seeds | Genes | Science | Mites | Maize | Transgenic plants | Immunity | Allelochemicals | Communication | Organic compounds | Corn | Pest control | Priming | Herbivory | Metabolism | Volatiles | Biological diversity | Studies | Ocimene | Tobacco | Animal behavior | Genetic engineering | Volatile compounds | Herbivores | Volatile organic compounds--VOCs | Larval development | VOCs
Journal Article
Bulletin of Entomological Research, ISSN 0007-4853, 4/2005, Volume 95, Issue 2, pp. 69 - 114
Aerial dispersal using silk ('ballooning') has evolved in spiders (Araneae), spider mites (Acari) and in the larvae of moths (Lepidoptera). Since the 17th...
GYPSY-MOTH LEPIDOPTERA | AERIAL-DISPERSAL | 2-SPOTTED SPIDER-MITE | TETRANYCHUS-URTICAE ACARI | LYMANTRIA-DISPAR L | BANKS GRASS MITE | LARVAL DISPERSAL | OPEROPHTERA-BRUMATA | ENTOMOLOGY | WIND DISPERSAL | LINYPHIID SPIDERS | Tetranychidae - genetics | Behavior, Animal - physiology | Flight, Animal | Silk - physiology | Phylogeny | Tetranychidae - physiology | Moths - genetics | Animals | Models, Biological | Moths - physiology | Environment | Larva - physiology | Spiders - genetics | Spiders - physiology
GYPSY-MOTH LEPIDOPTERA | AERIAL-DISPERSAL | 2-SPOTTED SPIDER-MITE | TETRANYCHUS-URTICAE ACARI | LYMANTRIA-DISPAR L | BANKS GRASS MITE | LARVAL DISPERSAL | OPEROPHTERA-BRUMATA | ENTOMOLOGY | WIND DISPERSAL | LINYPHIID SPIDERS | Tetranychidae - genetics | Behavior, Animal - physiology | Flight, Animal | Silk - physiology | Phylogeny | Tetranychidae - physiology | Moths - genetics | Animals | Models, Biological | Moths - physiology | Environment | Larva - physiology | Spiders - genetics | Spiders - physiology
Journal Article
Nature, ISSN 0028-0836, 11/2011, Volume 479, Issue 7374, pp. 487 - 492
The spider mite Tetranychus urticae is a cosmopolitan agricultural pest with an extensive host plant range and an extreme record of pesticide resistance. Here...
MITE | HOX GENES | MODEL | MULTIDISCIPLINARY SCIENCES | SPIDER | Multigene Family - genetics | Tetranychidae - genetics | Herbivory - physiology | Plants - parasitology | Genomics | Gene Expression Regulation | Genome - genetics | Molting - genetics | Adaptation, Physiological - physiology | Fibroins - genetics | Molecular Sequence Data | Transcriptome - genetics | Genes, Homeobox - genetics | Tetranychidae - physiology | Ecdysterone - analogs & derivatives | Ecdysterone - genetics | Silk - biosynthesis | Animals | Herbivory - genetics | Adaptation, Physiological - genetics | Nanostructures - chemistry | Gene Transfer, Horizontal - genetics | Silk - chemistry | Evolution, Molecular | Tetranychidae | Genetic aspects | Genomes | Models | Food and nutrition | Agricultural pests | Natural history | Biomedical materials | Pesticides | DNA methylation | Genetics | Chromosomes
MITE | HOX GENES | MODEL | MULTIDISCIPLINARY SCIENCES | SPIDER | Multigene Family - genetics | Tetranychidae - genetics | Herbivory - physiology | Plants - parasitology | Genomics | Gene Expression Regulation | Genome - genetics | Molting - genetics | Adaptation, Physiological - physiology | Fibroins - genetics | Molecular Sequence Data | Transcriptome - genetics | Genes, Homeobox - genetics | Tetranychidae - physiology | Ecdysterone - analogs & derivatives | Ecdysterone - genetics | Silk - biosynthesis | Animals | Herbivory - genetics | Adaptation, Physiological - genetics | Nanostructures - chemistry | Gene Transfer, Horizontal - genetics | Silk - chemistry | Evolution, Molecular | Tetranychidae | Genetic aspects | Genomes | Models | Food and nutrition | Agricultural pests | Natural history | Biomedical materials | Pesticides | DNA methylation | Genetics | Chromosomes
Journal Article
Journal of Insect Physiology, ISSN 0022-1910, 01/2017, Volume 96, pp. 73 - 81
The performance of the two-spotted spider mite, Koch, on plants depends on the rate of adaptation of mite populations to each particular host and can be...
Climate change | Spider mite | Plant-mite interaction | Digestion | Nutrition | Detoxification | POPULATION | PHYSIOLOGY | ACARI | ENTOMOLOGY | WATER-DEFICIT | DEFENSES | METABOLISM | 2-SPOTTED SPIDER-MITE | ADAPTATION | RESISTANCE | CONSEQUENCES | PLANTS | Adaptation, Physiological | Nymph - physiology | Herbivory | Nymph - growth & development | Tetranychidae - physiology | Lycopersicon esculentum - physiology | Animals | Droughts | Larva - growth & development | Female | Larva - physiology | Plant Physiological Phenomena | Tetranychidae - growth & development
Climate change | Spider mite | Plant-mite interaction | Digestion | Nutrition | Detoxification | POPULATION | PHYSIOLOGY | ACARI | ENTOMOLOGY | WATER-DEFICIT | DEFENSES | METABOLISM | 2-SPOTTED SPIDER-MITE | ADAPTATION | RESISTANCE | CONSEQUENCES | PLANTS | Adaptation, Physiological | Nymph - physiology | Herbivory | Nymph - growth & development | Tetranychidae - physiology | Lycopersicon esculentum - physiology | Animals | Droughts | Larva - growth & development | Female | Larva - physiology | Plant Physiological Phenomena | Tetranychidae - growth & development
Journal Article
Applied and Environmental Microbiology, ISSN 0099-2240, 03/2018, Volume 84, Issue 6
Spider mites are frequently associated with multiple endosymbionts whose infection patterns often exhibit spatial and temporal variation. However, the...
Multiple infections | Spider mite | Facultative bacterial endosymbionts | NATURAL-POPULATIONS | CYTOPLASMIC INCOMPATIBILITY | DROSOPHILA-MELANOGASTER | MICROBIOLOGY | HORIZONTAL TRANSMISSION | ACARI TETRANYCHIDAE | spider mite | SYMBIOTIC BACTERIA | BIOTECHNOLOGY & APPLIED MICROBIOLOGY | facultative bacterial endosymbionts | TETRANYCHUS-URTICAE | INFECTION | WOLBACHIA | multiple infections | PEA APHID | Soybeans - growth & development | Symbiosis | Animals | Lycopersicon esculentum - growth & development | China | Spiroplasma - physiology | Environment | Tetranychidae - physiology | Wolbachia - physiology | Zea mays - growth & development | Bacteroidetes - physiology | Tetranychidae - microbiology | Physiological aspects | Genetic aspects | Tetranychidae | Analysis | Biological diversity
Multiple infections | Spider mite | Facultative bacterial endosymbionts | NATURAL-POPULATIONS | CYTOPLASMIC INCOMPATIBILITY | DROSOPHILA-MELANOGASTER | MICROBIOLOGY | HORIZONTAL TRANSMISSION | ACARI TETRANYCHIDAE | spider mite | SYMBIOTIC BACTERIA | BIOTECHNOLOGY & APPLIED MICROBIOLOGY | facultative bacterial endosymbionts | TETRANYCHUS-URTICAE | INFECTION | WOLBACHIA | multiple infections | PEA APHID | Soybeans - growth & development | Symbiosis | Animals | Lycopersicon esculentum - growth & development | China | Spiroplasma - physiology | Environment | Tetranychidae - physiology | Wolbachia - physiology | Zea mays - growth & development | Bacteroidetes - physiology | Tetranychidae - microbiology | Physiological aspects | Genetic aspects | Tetranychidae | Analysis | Biological diversity
Journal Article
PLoS ONE, ISSN 1932-6203, 05/2018, Volume 13, Issue 5, p. e0197633
Calcium is an important second messenger in plants that is released into the cytosol early after recognition of various environmental stimuli. Decoding of such...
TRANSITION | SPODOPTERA-LITTORALIS | INSECT HERBIVORES | ABIOTIC STRESS | INDUCED RESISTANCE | MULTIDISCIPLINARY SCIENCES | CALCIUM | INFECTION | MUTATIONS | ABSCISIC-ACID | EXPRESSION | Arabidopsis - physiology | Arabidopsis Proteins - physiology | Calmodulin - metabolism | Tetranychidae | Plant Growth Regulators - physiology | Alternaria | Plant Diseases - microbiology | Herbivory | Arabidopsis - metabolism | Arabidopsis Proteins - metabolism | Calmodulin - physiology | Oxylipins - metabolism | Animals | Cyclopentanes - metabolism | Plant Growth Regulators - metabolism | Arabidopsis thaliana | Physiological aspects | Research | Calmodulin | Risk factors | Calcium | Infections | Cytosol | Proteins | Fungi | Calcium signalling | Signal transduction | Calcium-binding protein | Abscisic acid | Physiology | Sensors | Drought | Stress response | Deoxyribonucleic acid--DNA | Jasmonic acid | Stresses | Salicylic acid | Pathogens | Decoding | Stress | Environmental effects | Investigations | Feeding | Wounding | Chemistry | Insects | Herbivores | Deoxyribonucleic acid | DNA
TRANSITION | SPODOPTERA-LITTORALIS | INSECT HERBIVORES | ABIOTIC STRESS | INDUCED RESISTANCE | MULTIDISCIPLINARY SCIENCES | CALCIUM | INFECTION | MUTATIONS | ABSCISIC-ACID | EXPRESSION | Arabidopsis - physiology | Arabidopsis Proteins - physiology | Calmodulin - metabolism | Tetranychidae | Plant Growth Regulators - physiology | Alternaria | Plant Diseases - microbiology | Herbivory | Arabidopsis - metabolism | Arabidopsis Proteins - metabolism | Calmodulin - physiology | Oxylipins - metabolism | Animals | Cyclopentanes - metabolism | Plant Growth Regulators - metabolism | Arabidopsis thaliana | Physiological aspects | Research | Calmodulin | Risk factors | Calcium | Infections | Cytosol | Proteins | Fungi | Calcium signalling | Signal transduction | Calcium-binding protein | Abscisic acid | Physiology | Sensors | Drought | Stress response | Deoxyribonucleic acid--DNA | Jasmonic acid | Stresses | Salicylic acid | Pathogens | Decoding | Stress | Environmental effects | Investigations | Feeding | Wounding | Chemistry | Insects | Herbivores | Deoxyribonucleic acid | DNA
Journal Article
Transgenic Research, ISSN 0962-8819, 2/2016, Volume 25, Issue 1, pp. 33 - 44
Crops producing insecticidal crystal (Cry) proteins from the bacterium, Bacillus thuringiensis (Bt), are an important tool for managing lepidopteran pests on...
Transgenics | Tri-trophic exposure | Environmental risk assessment | Biomedicine | Biological control | Molecular Medicine | Cry1F | Cry1Ac | Cry2Ab | Plant Sciences | Plant Genetics & Genomics | Animal Genetics and Genomics | TOXIN | BIOCHEMISTRY & MOLECULAR BIOLOGY | BIOCHEMICAL RESEARCH METHODS | METAANALYSIS RESPONSE | PERSIMILIS ATHIAS-HENRIOT | NONTARGET | RESISTANT | PREY | BIOTECHNOLOGY & APPLIED MICROBIOLOGY | PREDACIOUS MITES | TRANSGENIC INSECTICIDAL CROPS | BT-MAIZE | DIGESTIVE PHYSIOLOGY | Predatory Behavior - physiology | Pest Control, Biological | Plants, Genetically Modified - physiology | Risk Assessment - methods | Zea mays - genetics | Endotoxins - genetics | Herbivory - physiology | Hemolysin Proteins - genetics | Bacterial Proteins - genetics | Tetranychidae - physiology | Gossypium - physiology | Animals | Larva | Plant Leaves - genetics | Plant Leaves - metabolism | Fertility | Gossypium - genetics | Zea mays - physiology | Crops, Agricultural | Receptors, Cell Surface - genetics | Proteins | Biotechnology | Genetically modified crops | Genetically engineered foods | Corn | Pests | Food
Transgenics | Tri-trophic exposure | Environmental risk assessment | Biomedicine | Biological control | Molecular Medicine | Cry1F | Cry1Ac | Cry2Ab | Plant Sciences | Plant Genetics & Genomics | Animal Genetics and Genomics | TOXIN | BIOCHEMISTRY & MOLECULAR BIOLOGY | BIOCHEMICAL RESEARCH METHODS | METAANALYSIS RESPONSE | PERSIMILIS ATHIAS-HENRIOT | NONTARGET | RESISTANT | PREY | BIOTECHNOLOGY & APPLIED MICROBIOLOGY | PREDACIOUS MITES | TRANSGENIC INSECTICIDAL CROPS | BT-MAIZE | DIGESTIVE PHYSIOLOGY | Predatory Behavior - physiology | Pest Control, Biological | Plants, Genetically Modified - physiology | Risk Assessment - methods | Zea mays - genetics | Endotoxins - genetics | Herbivory - physiology | Hemolysin Proteins - genetics | Bacterial Proteins - genetics | Tetranychidae - physiology | Gossypium - physiology | Animals | Larva | Plant Leaves - genetics | Plant Leaves - metabolism | Fertility | Gossypium - genetics | Zea mays - physiology | Crops, Agricultural | Receptors, Cell Surface - genetics | Proteins | Biotechnology | Genetically modified crops | Genetically engineered foods | Corn | Pests | Food
Journal Article
New Phytologist, ISSN 0028-646X, 06/2017, Volume 214, Issue 4, pp. 1688 - 1701
- Spider mites are destructive arthropod pests on many crops. The generalist herbivorous mite Tetranychus urticae induces defenses in tomato (Solanum...
Journal Article | tomato (Solanum lycopersicum) | defense suppression | overcompensation | plant‐mediated interactions | Tetranychus urticae | spider mites | Tetranychus evansi | competition | plant-mediated interactions | INSECT HERBIVORES | COMPENSATORY GROWTH | ACARI TETRANYCHIDAE | HOST-PLANT | PLANT SCIENCES | TRADE-OFF | COMMUNITY | 2-SPOTTED SPIDER-MITE | TETRANYCHUS-URTICAE | JASMONIC ACID | TOMATO | Tetranychidae - genetics | Phaseolus - physiology | Salicylic Acid - metabolism | Male | Herbivory | Tetranychidae - physiology | Lycopersicon esculentum - physiology | Oxylipins - metabolism | Animals | Gene Expression Regulation, Plant | Cyclopentanes - metabolism | Female | Plant Growth Regulators - metabolism | Plant Leaves - physiology | Proteins |
Journal Article | tomato (Solanum lycopersicum) | defense suppression | overcompensation | plant‐mediated interactions | Tetranychus urticae | spider mites | Tetranychus evansi | competition | plant-mediated interactions | INSECT HERBIVORES | COMPENSATORY GROWTH | ACARI TETRANYCHIDAE | HOST-PLANT | PLANT SCIENCES | TRADE-OFF | COMMUNITY | 2-SPOTTED SPIDER-MITE | TETRANYCHUS-URTICAE | JASMONIC ACID | TOMATO | Tetranychidae - genetics | Phaseolus - physiology | Salicylic Acid - metabolism | Male | Herbivory | Tetranychidae - physiology | Lycopersicon esculentum - physiology | Oxylipins - metabolism | Animals | Gene Expression Regulation, Plant | Cyclopentanes - metabolism | Female | Plant Growth Regulators - metabolism | Plant Leaves - physiology | Proteins |