Constraints on effectiveness of cyanogenic glycosides in herbivore defense
about
sameAs
Get Tough, Get Toxic, or Get a Bodyguard: Identifying Candidate Traits Conferring Belowground Resistance to Herbivores in GrassesTurning the 'mustard oil bomb' into a 'cyanide bomb': aromatic glucosinolate metabolism in a specialist insect herbivoreChemical defense balanced by sequestration and de novo biosynthesis in a lepidopteran specialistDifferential phenotypic and genetic expression of defence compounds in a plant-herbivore interaction along elevationForward Genetics by Genome Sequencing Reveals That Rapid Cyanide Release Deters Insect Herbivory of Sorghum bicolorCharting biologically relevant chemical space: a structural classification of natural products (SCONP)Dynamic size responses to climate change: prevailing effects of rising temperature drive long-term body size increases in a semi-arid passerine.Resilience of cassava (Manihot esculenta Crantz) to salinity: implications for food security in low-lying regions.A gene horizontally transferred from bacteria protects arthropods from host plant cyanide poisoning.Effect of harvesting frequency, variety and leaf maturity on nutrient composition, hydrogen cyanide content and cassava foliage yield.Salinity-mediated cyanogenesis in white clover (Trifolium repens) affects trophic interactions.The cyanogenic syndrome in rubber tree Hevea brasiliensis: tissue-damage-dependent activation of linamarase and hydroxynitrile lyase accelerates hydrogen cyanide release.South American leaf blight of the rubber tree (Hevea spp.): new steps in plant domestication using physiological features and molecular markers.Why are defensive toxins so variable? An evolutionary perspective.CYP79 P450 monooxygenases in gymnosperms: CYP79A118 is associated with the formation of taxiphyllin in Taxus baccata.Drying and processing protocols affect the quantification of cyanogenic glucosides in forage sorghum.Effects of cyanogenic plants on fitness in two host strains of the fall armyworm (Spodoptera frugiperda).How insects overcome two-component plant chemical defence: plant β-glucosidases as the main target for herbivore adaptation.Aridity shapes cyanogenesis cline evolution in white clover (Trifolium repens L.).Frequency of cyanogenesis in tropical rainforests of far north Queensland, Australia.Gamma irradiation of medicinally important plants and the enhancement of secondary metabolite production.Microbial community function in the bleaching disease of the marine macroalgae Delisea pulchra.Light affects in vitro organogenesis of Linum usitatissimum L. and its cyanogenic potential.Diversified glucosinolate metabolism: biosynthesis of hydrogen cyanide and of the hydroxynitrile glucoside alliarinoside in relation to sinigrin metabolism in Alliaria petiolata.Variation in cyanogenic glycosides across populations of wild lima beans (Phaseolus lunatus) has no apparent effect on bruchid beetle performance.Jasmonic acid enhances plant cyanogenesis and resistance to herbivory in lima bean.The beta-glucosidases responsible for bioactivation of hydroxynitrile glucosides in Lotus japonicus.Distribution of amygdalin in apricot (Prunus armeniaca) seeds studied by Raman microscopic imaging.Changes in nutritional value of cyanogenic trifolium repens grown at elevated atmospheric CO2.Chemicals on plant surfaces as a heretofore unrecognized, but ecologically informative, class for investigations into plant defence.Label-free Raman hyperspectral imaging analysis localizes the cyanogenic glucoside dhurrin to the cytoplasm in sorghum cells.Pollination and plant defence traits co-vary in Western Australian Hakeas.Cyanogenic myrmecophytes, redundant defence mechanisms and complementary defence syndromes: revisiting the neotropical ant-acacias.Constraints of simultaneous resistance to a fungal pathogen and an insect herbivore in lima bean (Phaseolus lunatus L.).Cyanogenesis in Arthropods: From Chemical Warfare to Nuptial Gifts.A combined biochemical screen and TILLING approach identifies mutations in Sorghum bicolor L. Moench resulting in acyanogenic forage productionPotential Mechanism of Detoxification of Cyanide Compounds by Gut Microbiomes of Bamboo-Eating Pandas.Reconfigured cyanogenic glucoside biosynthesis in Eucalyptus cladocalyx involves a cytochrome P450 CYP706C55
P2860
Q28468425-0574B517-4FBE-498B-8A29-34A9824EEA75Q28482461-22B8D4BB-DC0F-4988-901B-E82FF8CB3C52Q28543653-6B011A77-D1C4-4A5B-8170-F7F307FA3D25Q28598170-EF11650C-C6F6-4345-B743-2FE6FBEDFD0FQ30040556-1BE31324-4F63-4C37-A25E-0D6ECFF3BD30Q30351855-F39861C7-FC19-4C77-BA88-61A2FAF4CADCQ30885084-D1D75416-9AEC-43F8-8D21-DA70830DF67EQ31120583-8B123FC1-2374-48B9-B411-D35C7D778BB1Q33570872-E7CD7960-8AF5-455D-979F-3B067DAA8D06Q33888909-5582F5AD-562A-4804-B41B-F351625F41FEQ33951863-E413065D-FED5-4562-ACBF-AF6E22680DCFQ34208896-71AEEF17-3E04-4E24-9041-62E0DC015244Q36890697-BF17840B-5224-4525-919C-2F3072666C09Q38006035-2DF82DF0-558A-4C82-BBB6-2E659A46EEBDQ38631147-261797AC-7E18-4035-A8FA-3231AF75F60BQ39025082-1C0A8C52-A18C-4D54-9C80-2C8E79E49A94Q39059142-1B22D77A-BB08-45B6-A4A3-37AE0DBF7598Q39138542-C78C9821-3502-4D07-9498-53EAC53D202AQ39145203-3D4ED75F-A452-4389-AC83-8276226B8C9CQ39251593-31FCBD71-C2DB-4F54-8E89-76D1F5464B4DQ39438719-94DA67C0-4F21-473C-A3FC-517DB9D4ECE5Q40246717-6AE167E3-A5B2-4F6C-9ABC-DA70FA7B9960Q41124528-473EE833-8543-43EA-8EB7-6929E6969741Q41840265-057F417B-CBAD-4FF9-A781-B4B794EB21EAQ44923212-BF57A587-3E3A-4DC8-A2B3-420766EF6305Q45047898-5C394C6E-3B6D-476C-820F-256BB4E8AC7FQ46604360-03152C90-C26A-43DB-8E5C-7C1C3EBBFD00Q47578682-0911E6E4-B166-4504-BBCD-8040F333FEDAQ48034633-E7767F5C-673F-4E5F-BDCD-82CADB79C9D0Q48579622-EA407154-CFE1-460D-B3C5-A09B491C38A6Q49727362-91750A29-C0DB-447B-B9E8-87B65FB5D519Q50625149-845454FA-DB64-42FE-9550-8D804C2BBC7DQ52697148-7502CFDD-9DBA-484B-9448-139191893E4BQ52713705-AA47E67A-5C92-4DC7-B690-F94BEBAD972AQ55112849-E103B49D-0921-4B54-93E3-9287541F3CB4Q55113106-AAB544C3-75AD-43D1-8E45-D69FBBEC2046Q55286967-01BF76CD-77AF-4530-B8D3-6DA3678FFD34Q57295866-47B303FE-79F7-401B-BBAD-AFE8DD1724C9
P2860
Constraints on effectiveness of cyanogenic glycosides in herbivore defense
description
2002 nî lūn-bûn
@nan
2002 թուականի Յուլիսին հրատարակուած գիտական յօդուած
@hyw
2002 թվականի հուլիսին հրատարակված գիտական հոդված
@hy
2002年の論文
@ja
2002年論文
@yue
2002年論文
@zh-hant
2002年論文
@zh-hk
2002年論文
@zh-mo
2002年論文
@zh-tw
2002年论文
@wuu
name
Constraints on effectiveness of cyanogenic glycosides in herbivore defense
@ast
Constraints on effectiveness of cyanogenic glycosides in herbivore defense
@en
Constraints on effectiveness of cyanogenic glycosides in herbivore defense
@nl
type
label
Constraints on effectiveness of cyanogenic glycosides in herbivore defense
@ast
Constraints on effectiveness of cyanogenic glycosides in herbivore defense
@en
Constraints on effectiveness of cyanogenic glycosides in herbivore defense
@nl
prefLabel
Constraints on effectiveness of cyanogenic glycosides in herbivore defense
@ast
Constraints on effectiveness of cyanogenic glycosides in herbivore defense
@en
Constraints on effectiveness of cyanogenic glycosides in herbivore defense
@nl
P3181
P356
P1476
Constraints on effectiveness of cyanogenic glycosides in herbivore defense
@en
P2093
Ian E Woodrow
Roslyn M Gleadow
P2888
P304
P3181
P356
10.1023/A:1016298100201
P407
P577
2002-07-01T00:00:00Z
P6179
1000065150