Intake and transformation to a glycoside of (Z)-3-hexenol from infested neighbors reveals a mode of plant odor reception and defense - Wikidata - wikimedia - TriplyDB

Intake and transformation to a glycoside of (Z)-3-hexenol from infested neighbors reveals a mode of plant odor reception and defense

Intake and transformation to a glycoside of (Z)-3-hexenol from infested neighbors reveals a mode of plant odor reception and defense

http://www.wikidata.org/entity/Q33627156

about

Recent Advances in the Emission and Functions of Plant Vegetative Volatiles Mechanisms and ecological consequences of plant defence induction and suppression in herbivore communities Generation of Triple-Transgenic Forsythia Cell Cultures as a Platform for the Efficient, Stable, and Sustainable Production of Lignans.Priming by Hexanoic Acid Induce Activation of Mevalonic and Linolenic Pathways and Promotes the Emission of Plant Volatiles Recent Advances in the Application of Metabolomics to Studies of Biogenic Volatile Organic Compounds (BVOC) Produced by Plant.Role of plant sensory perception in plant-animal interactions.Jasmonates induce both defense responses and communication in monocotyledonous and dicotyledonous plants.Language of plants: Where is the word?Green leaf volatile production by plants: a meta-analysis.Weeding volatiles reduce leaf and seed damage to field-grown soybeans and increase seed isoflavones.Plant volatile-mediated signalling and its application in agriculture: successes and challenges.Terpenoids in plant and arbuscular mycorrhiza-reinforced defence against herbivorous insects.Carnivore Attractant or Plant Elicitor? Multifunctional Roles of Methyl Salicylate Lures in Tomato Defense.Volatile Glycosylation in Tea Plants: Sequential Glycosylations for the Biosynthesis of Aroma β-Primeverosides Are Catalyzed by Two Camellia sinensis Glycosyltransferases.WRKY40 and WRKY6 act downstream of the green leaf volatile E-2-hexenal in Arabidopsis.Conversion of volatile alcohols into their glucosides in Arabidopsis.Identification of an insect-produced olfactory cue that primes plant defenses.Indole is an essential herbivore-induced volatile priming signal in maize.Volatile-Mediated Interactions between Cabbage Plants in the Field and the Impact of Ozone Pollution.Geographic dialects in volatile communication between sagebrush individuals.Forward genetic screens identify a role for the mitochondrial HER2 in E-2-hexenal responsiveness.Glutathionylation and Reduction of Methacrolein in Tomato Plants Account for Its Absorption from the Vapor Phase.Biochemical characterization of allene oxide synthases from the liverwort Marchantia polymorpha and green microalgae Klebsormidium flaccidum provides insight into the evolutionary divergence of the plant CYP74 family.Modification of chrysanthemum odour and taste with chrysanthemol synthase induces strong dual resistance against cotton aphids.Perfluorodecalins and Hexenol as Inducers of Secondary Metabolism in Taxus media and Vitis vinifera Cell Cultures.An herbivore-induced plant volatile reduces parasitoid attraction by changing the smell of caterpillars.Volatile β-Ocimene Can Regulate Developmental Performance of Peach Aphid Myzus persicae Through Activation of Defense Responses in Chinese Cabbage Brassica pekinensis.Revisiting bacterial volatile-mediated plant growth promotion: lessons from the past and objectives for the future Transcriptome analysis of treated with green leaf volatiles: possible role of green leaf volatiles as self-made damage-associated molecular patterns Identification of a Hexenal Reductase That Modulates the Composition of Green Leaf Volatiles

P2860

Q26775151-5350EB9B-4573-47B5-B0D6-052EB8388928 Q35644236-4030B7CA-5B9F-494D-BBC0-74FE6A4B775D Q35862053-5EE6F43F-EF21-47EA-A6FA-7D466130F0FC Q36789129-5DBB26A2-C33F-41E6-9BFE-7D38C095E2E2 Q38254533-34757F10-83DF-4434-8A91-6DE6FF9F4BC2 Q38265152-8ADCD1E3-88C6-4808-88B2-EAC394EEE16B Q38266010-FFBB12C5-2297-413E-9AFB-0B74253B29D2 Q38632252-9B7650CF-8E70-4719-90CC-B23AC8E9F74F Q38700589-23F388C9-C477-46DF-BC41-5B55478D9C59 Q38764477-170EF4F0-46C3-4AB9-9CFF-1E8F7F74685D Q39016623-758B59E6-A5F4-4F58-B320-78535C43924B Q39088180-6A98BA72-C1CF-404D-9F41-5A7FA66438E8 Q40178195-AF8F64AE-0FE9-45C1-8CED-6567471A6ADA Q41002014-EE9956B1-F039-445B-8E03-DC5EC13E5F2C Q41071722-C1475461-0F73-474D-90A5-2D24836B40AC Q41288901-8008629E-8B6D-435C-ADCB-18A6B8DE97E4 Q41504218-B724393F-F73B-4892-9DAB-171D5FC08193 Q41835971-06FED7B5-20A1-4867-A09A-B78E8B6CFFCE Q41987360-08844B58-3289-4F25-A569-920695815827 Q44606770-313189AD-D800-4CB1-AB5F-455E75F934C3 Q46305797-4C00A27C-7225-47C5-9EA4-49F95F129346 Q46701374-587DF440-B947-48F7-834A-F3E200304A5B Q46710562-FFABF1AF-02AF-4B5E-B1C6-ACFB5D0E6CDB Q50056686-978EBED2-6B16-49EF-BE9B-BBD3F044F23B Q52608517-736086D7-D75A-4914-9353-B7A7CE2003C7 Q55226709-4AB0CC54-D769-4CF2-98D8-82FCC3BE6E65 Q55259159-E7D50D5B-52D0-409A-AA37-4F97F6237C87 Q57167317-25AFDA50-14DC-42F3-869E-A56A91F183B7 Q58564941-9B48AF7B-6031-4214-A744-A1B2B2C1D6B1 Q58732473-2398E37F-F64D-49F6-90EF-DD7DA10DD924

P2860

Intake and transformation to a glycoside of (Z)-3-hexenol from infested neighbors reveals a mode of plant odor reception and defense

http://www.wikidata.org/entity/Q33627156

description

2014 nî lūn-bûn

@nan

2014 թուականի Ապրիլին հրատարակուած գիտական յօդուած

@hyw

2014 թվականի ապրիլին հրատարակված գիտական հոդված

@hy

2014年の論文

@ja

2014年論文

@yue

2014年論文

@zh-hant

2014年論文

@zh-hk

2014年論文

@zh-mo

2014年論文

@zh-tw

2014年论文

@wuu

name

Intake and transformation to a ...... ant odor reception and defense

@ast

Intake and transformation to a ...... ant odor reception and defense

@en

type

label

Intake and transformation to a ...... ant odor reception and defense

@ast

Intake and transformation to a ...... ant odor reception and defense

@en

prefLabel

Intake and transformation to a ...... ant odor reception and defense

@ast

Intake and transformation to a ...... ant odor reception and defense

@en

P1433

Q33627156-FE6F2DCE-ADA0-41DD-857D-074D79406653

P1476

Q33627156-65DD6E36-3DA1-4BA4-9045-430F32A8E2A1

P2093

Q33627156-161133C6-DBED-4696-B424-5C29B93DF99E

Q33627156-1E75D778-C66E-4168-8E2F-8CBB45FCD3F1

Q33627156-29FCCFC9-AFD2-4D28-B8D5-27027316ECCC

Q33627156-2C05235D-6B05-40E7-8FE1-11BC7BBEBAF3

Q33627156-666A6241-6A2C-4C9F-971D-7BA8DC1EE0DD

Q33627156-7A295FD0-60B7-49C5-B9E6-FE568F545388

Q33627156-7E45A8DC-5650-4A63-896E-F3492217C4AB

Q33627156-82F3BB55-C962-419F-B5AE-590FBD5DA73B

Q33627156-A2F29369-A13A-4D61-BAD0-9D8BF41CE19F

Q33627156-AA8CD8A2-665D-48BD-B3CF-11C055961175

P2860

Q33627156-074D81DC-431E-4555-BBBC-A220446E86BF

Q33627156-11C18A16-7260-43C0-A23E-AF77AA4FD46C

Q33627156-15BED726-9B3E-43D8-94B8-40DA5532B2DB

Q33627156-28E361D3-B9F1-483D-9964-ECA25489386D

Q33627156-2F1E1CE0-CFAE-42D0-A917-75901874CC7A

Q33627156-3366307D-29EE-46F3-AFE1-73158CFBE741

Q33627156-5A8A6119-0647-4895-BBDF-08C6FE286753

Q33627156-6FA6FF61-8F60-4B4F-9DB8-E3CEE46C9573

Q33627156-75C602B7-4E3D-4AA4-9A97-4EC56363A492

Q33627156-78768721-66C8-4ECF-9AE4-EAFCA2C7FAE1

P304

Q33627156-2A0B3C2F-C3CB-44C5-9533-A56B9BFF38C7

P31

Q33627156-CD9AF588-C8BB-4589-86C8-F28DF2D6CEE9

P356

Q33627156-C2FE3599-8F40-48D4-AB8C-111BE960AD96

P407

Q33627156-33BD53F8-F862-4D2B-BCD8-978979E64BB2

P433

Q33627156-404E17CA-7536-48FA-902D-09AEDC5618AA

P478

Q33627156-877A8941-3FEA-4071-A35F-8D1283EBC083

P50

Q33627156-1F56932E-C381-4FD6-9D2C-6625E9D266CE

Q33627156-B1C7DB25-AD47-4524-8112-6DE78BB261CD

Q33627156-DF0D76A9-3B6B-4AE9-9704-0558AAF546F1

P577

Q33627156-05C78FC9-8E18-4B95-841B-DEC933AF7500

P5875

Q33627156-36520B5D-4976-4CA3-83EB-1676CBC12D1F

P698

Q33627156-DEB464FB-5B77-4199-83ED-F57FF5D9A27D

P932

Q33627156-8D980191-0866-4CA4-82AA-7915668AE14A

P356

PNAS.1320660111

P1433

Proceedings of the National Academy of Sciences of the United States of America

P1476

Intake and transformation to a ...... ant odor reception and defense

@en

P2093

Daisuke Shibata

http://www.w3.org/2001/XMLSchema#string

Kabir Md Alamgir

http://www.w3.org/2001/XMLSchema#string

Kenji Matsui

http://www.w3.org/2001/XMLSchema#string

Koh Aoki

http://www.w3.org/2001/XMLSchema#string

Masayoshi Uefune

http://www.w3.org/2001/XMLSchema#string

Rika Ozawa

http://www.w3.org/2001/XMLSchema#string

Ryosuke Sasaki

http://www.w3.org/2001/XMLSchema#string

Shoko Muramoto

http://www.w3.org/2001/XMLSchema#string

Shota Akitake

http://www.w3.org/2001/XMLSchema#string

Tatsunori Nobuke

http://www.w3.org/2001/XMLSchema#string

P2860

Smelling global climate change: mitigation of function for plant volatile organic compounds.

A free lunch? No cost for acquiring defensive plant pyrrolizidine alkaloids in a specialist arctiid moth (Utetheisa ornatrix).

(Z)-3-Hexenol induces defense genes and downstream metabolites in maize.

Ecological trade-offs between jasmonic acid-dependent direct and indirect plant defences in tritrophic interactions

Tetrodotoxin--distribution and accumulation in aquatic organisms, and cases of human intoxication.

Chemical and molecular ecology of herbivore-induced plant volatiles: proximate factors and their ultimate functions.

Two-component signaling elements and histidyl-aspartyl phosphorelays

Airborne signals prime plants against insect herbivore attack.

The evolutionary context for herbivore-induced plant volatiles: beyond the 'cry for help'.

Molecular plant volatile communication.

P304

7144-7149

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1073/PNAS.1320660111

http://www.w3.org/2001/XMLSchema#string

P407

P433

19

http://www.w3.org/2001/XMLSchema#string

P478

111

http://www.w3.org/2001/XMLSchema#string

P50

Junji Takabayashi

Koichi Sugimoto

P577

2014-04-28T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

261956560

http://www.w3.org/2001/XMLSchema#string

P698

24778218

http://www.w3.org/2001/XMLSchema#string

P932

4024874

http://www.w3.org/2001/XMLSchema#string