Direct and indirect chemical defence of pine against folivorous insects.
about
Ecological genomics of plant-insect interactions: from gene to communityDifferential allocation of constitutive and induced chemical defenses in pine tree juveniles: a test of the optimal defense theoryDefensive Traits in Young Pine Trees Cluster into Two Divergent Syndromes Related to Early Growth RateThe response of an egg parasitoid to substrate-borne semiochemicals is affected by previous experienceGenetic variation in jasmonic acid- and spider mite-induced plant volatile emission of cucumber accessions and attraction of the predator Phytoseiulus persimilis.An integrated genomic, proteomic and biochemical analysis of (+)-3-carene biosynthesis in Sitka spruce (Picea sitchensis) genotypes that are resistant or susceptible to white pine weevil.The ratio and concentration of two monoterpenes mediate fecundity of the pinewood nematode and growth of its associated fungi.Effects of volatiles from Maruca vitrata larvae and caterpillar-infested flowers of their host plant Vigna unguiculata on the foraging behavior of the parasitoid Apanteles taragamaeFlavonoid metabolites in the hemolymph of European pine sawfly (Neodiprion sertifer) larvae.Olive phenolic compounds: metabolic and transcriptional profiling during fruit development.Additive genetic variation in resistance traits of an exotic pine species: little evidence for constraints on evolution of resistance against native herbivores.Does egg deposition by herbivorous pine sawflies affect transcription of sesquiterpene synthases in pine?Jasmonic acid-induced changes in Brassica oleracea affect oviposition preference of two specialist herbivoresIdentification of Genes Potentially Responsible for extra-Oral Digestion and Overcoming Plant Defense from Salivary Glands of the Tarnished Plant Bug (Hemiptera: Miridae) Using cDNA Sequencing.Are the metabolomic responses to folivory of closely related plant species linked to macroevolutionary and plant-folivore coevolutionary processes?Laticifers and secretory ducts: two other tube systems in plants.Monoterpenes from larval frass of two Cerambycids as chemical cues for a parasitoid, Dastarcus helophoroides.Alternative Growth and Defensive Strategies Reveal Potential and Gender Specific Trade-Offs in Dioecious Plants Salix paraplesia to Nutrient Availability.Volatile organic compounds as non-invasive markers for plant phenotyping.Early plant defence against insect attack: involvement of reactive oxygen species in plant responses to insect egg deposition.Terpenoids in plant and arbuscular mycorrhiza-reinforced defence against herbivorous insects.Similar local, but different systemic, metabolomic responses of closely related pine subspecies to folivory by caterpillars of the processionary moth.Spruce Budworm (Lepidoptera: Tortricidae) Oral Secretions I: Biology and Function.Ectomycorrhizal fungi mediate indirect effects of a bark beetle outbreak on secondary chemistry and establishment of pine seedlings.Phenotypic plasticity of plant response to herbivore eggs: effects on resistance to caterpillars and plant development.Within-plant distribution of induced resistance in apple seedlings: rapid acropetal and delayed basipetal responses.Genetics, phosphorus availability, and herbivore-derived induction as sources of phenotypic variation of leaf volatile terpenes in a pine species.Quantification of monoterpene emission sources of a conifer species in response to experimental droughtResin duct characteristics associated with tree resistance to bark beetles across lodgepole and limber pines.Differential effects of plant ontogeny and damage type on phloem and foliage monoterpenes in jack pine (Pinus banksiana).Efficiency of plant induced volatiles in attracting Encarsia formosa and Serangium japonicum, two dominant natural enemies of whitefly Bemisia tabaci in China.Significance of terpenoids in induced indirect plant defence against herbivorous arthropods.The mono - and sesquiterpene content of aphid-induced galls on Pistacia palaestina is not a simple reflection of their composition in intact leaves.Trade-offs between constitutive and induced defences drive geographical and climatic clines in pine chemical defences.To grow or defend? Pine seedlings grow less but induce more defences when a key resource is limited.Macroecological and macroevolutionary patterns of leaf herbivory across vascular plants.Can insect egg deposition 'warn' a plant of future feeding damage by herbivorous larvae?Early resistance of alien and native pines against two native generalist insect herbivores: no support for the natural enemy hypothesisPhylogenetic and biogeographical patterns in defensive strategies and quantitative allocation to chemical defences in Palaearctic and Nearctic pine treesCold adaptation drives variability in needle structure and anatomy in Pinus sylvestris L. along a 1,900 km temperate-boreal transect
P2860
Q24657858-23DFA323-4676-45BF-9C61-5FEF643EEF4FQ28481717-B379A3F2-4731-4F94-B755-5C8B0A4C6309Q28551063-79E3FA80-A982-4E6D-88A0-6452C8AFC727Q28829461-A0635A31-FD0D-4BE7-89B8-89C0AFD3DFB2Q33836403-EB916A8C-6250-461C-8839-DB98A0D66137Q34164804-5A47D9D3-A656-44D6-85E1-893F5B2897AFQ34171292-847518E5-82B2-49AE-8B5F-03B6E908E087Q34185912-246BBD57-12CA-4A67-80B0-888971526E7DQ34270363-3546CA36-7BFE-4B3D-BF04-C52E557B426AQ34410439-1C920CAF-8D76-44DC-9C93-19D252E66876Q34509149-80599A13-7C04-4E5D-BCAF-4B86D4D52EE2Q34780065-EEB08404-D871-41CA-8A61-EA3849F02106Q35884289-1E90ECF3-E570-4C27-A773-674934EF3DDAQ36057275-3D41F662-11D4-46B5-8EEE-E8B8A83820C5Q36969861-B1F397DB-02FC-40EA-AD96-45349F4727ADQ37034473-7A97719C-4A30-492E-BE7F-99AF259AA7FCQ37088873-A1ABFAAC-E892-4BAD-A5C5-4F771E672DF3Q37110253-A97E3960-8A7A-45D2-B49D-4D4828F59190Q38476928-4D84A410-BAC1-457B-A37C-7B989D56622DQ38760113-0D0934C0-A402-4D3B-88A7-62DE0DFE27ADQ39088180-5018A9FE-AA64-424E-A932-C2889A861FA6Q40335835-2F64E9B6-7693-4468-893D-44D3906AF775Q40445447-B9F7B4F6-27D4-46D9-A45A-FE736AB4B3EFQ40880152-AF2E49E0-F2BF-4A9C-B6B5-EC02F0A29D78Q42008411-A5595EA8-15CE-493D-ACD4-5C0D02F25680Q42018158-8CC5FC52-F781-4D32-91BC-03715C6791FDQ42039916-4F3DF5DB-93B4-4D86-81AD-34DD41C82102Q42270800-C7689719-98EC-4BD4-935C-A799C32B1901Q43696181-22A18E35-16CA-4FDC-A7E8-C45B8FA875C8Q44085790-E01F7F7C-880B-45BF-8F8C-500262E170D0Q46012115-2CFB725C-B39C-419F-A2CE-4E0713D64D6DQ46798986-D570DB3A-5EFD-47E8-A831-63116FCFBC81Q46881295-17A8DEF9-6CB1-4086-848D-26DCFD3B4C35Q46895287-1856F484-9F15-4D29-B552-4928BBB623ECQ51369905-498353A1-A8AE-4787-9556-AB82946A093BQ51441963-AD567481-357E-44EC-A410-713754F8C656Q51709191-1F671317-C13F-40AC-A4E8-690AAF4E63DDQ56575827-2D035E3A-8CC1-4F22-BB7C-D1D883CDEF69Q56923503-A860AC27-34A9-4BD3-B96C-40B784DDB48FQ56965109-5D74CB15-7D36-4F2C-B5F9-BAD8B79F73EC
P2860
Direct and indirect chemical defence of pine against folivorous insects.
description
2006 nî lūn-bûn
@nan
2006年の論文
@ja
2006年論文
@yue
2006年論文
@zh-hant
2006年論文
@zh-hk
2006年論文
@zh-mo
2006年論文
@zh-tw
2006年论文
@wuu
2006年论文
@zh
2006年论文
@zh-cn
name
Direct and indirect chemical defence of pine against folivorous insects.
@ast
Direct and indirect chemical defence of pine against folivorous insects.
@en
type
label
Direct and indirect chemical defence of pine against folivorous insects.
@ast
Direct and indirect chemical defence of pine against folivorous insects.
@en
prefLabel
Direct and indirect chemical defence of pine against folivorous insects.
@ast
Direct and indirect chemical defence of pine against folivorous insects.
@en
P1476
Direct and indirect chemical defence of pine against folivorous insects.
@en
P2093
Monica Hilker
Roland Mumm
P304
P356
10.1016/J.TPLANTS.2006.05.007
P577
2006-07-01T00:00:00Z