Autoluminescence imaging: a non-invasive tool for mapping oxidative stress.
about
Biophoton emission induced by heat shockProduction of Reactive Oxygen Species by Photosystem II as a Response to Light and Temperature Stress.Singlet oxygen production in Chlamydomonas reinhardtii under heat stress.Linoleic acid-induced ultra-weak photon emission from Chlamydomonas reinhardtii as a tool for monitoring of lipid peroxidation in the cell membranes.Arabidopsis glutaredoxin S17 and its partner, the nuclear factor Y subunit C11/negative cofactor 2α, contribute to maintenance of the shoot apical meristem under long-day photoperiod.Vitamin B6 deficient plants display increased sensitivity to high light and photo-oxidative stress.Luminescence and fluorescence of essential oils. Fluorescence imaging in vivo of wild chamomile oil.Monitoring and screening plant populations with combined thermal and chlorophyll fluorescence imaging.Fluorescent chlorophyll catabolites in bananas light up blue halos of cell deathThermography to explore plant-environment interactions.Quality control of PSII: behavior of PSII in the highly crowded grana thylakoids under excessive light.Photo-oxidative stress markers as a measure of abiotic stress-induced leaf senescence: advantages and limitations.Formation of singlet oxygen by decomposition of protein hydroperoxide in photosystem II.Singlet oxygen detection in biological systems: Uses and limitations.Towards the two-dimensional imaging of spontaneous ultra-weak photon emission from microbial, plant and animal cells.Development of a configurable growth chamber with a computer vision system to study circadian rhythm in plants.Alr0397 is an outer membrane transporter for the siderophore schizokinen in Anabaena sp. strain PCC 7120.Light-induced acclimation of the Arabidopsis chlorina1 mutant to singlet oxygen.GOLLUM [FeFe]-hydrogenase-like proteins are essential for plant development in normoxic conditions and modulate energy metabolism.The relationship between skin aging and steady state ultraweak photon emission as an indicator of skin oxidative stress in vivo.Tocotrienols, the unsaturated forms of vitamin E, can function as antioxidants and lipid protectors in tobacco leaves.Carnosic Acid and Carnosol, Two Major Antioxidants of Rosemary, Act through Different Mechanisms.Unraveling the tapestry of networks involving reactive oxygen species in plants.Uncoupling High Light Responses from Singlet Oxygen Retrograde Signaling and Spatial-Temporal Systemic Acquired Acclimation.Vitamin E is essential for the tolerance of Arabidopsis thaliana to metal-induced oxidative stress.Zeaxanthin has enhanced antioxidant capacity with respect to all other xanthophylls in Arabidopsis leaves and functions independent of binding to PSII antennae.Peter Barlow's insights and contributions to the study of tidal gravity variations and ultra-weak light emissions in plants.Cryptogein-induced transcriptional reprogramming in tobacco is light dependent.Singlet Oxygen-Induced Cell Death in Arabidopsis under High-Light Stress Is Controlled by OXI1 Kinase.The Plastid Lipocalin LCNP is Required for Sustained Photoprotective Energy Dissipation in Arabidopsis.Singlet oxygen is the major reactive oxygen species involved in photooxidative damage to plants.Endogenous Chemiluminescence from Germinating Arabidopsis Thaliana Seeds
P2860
Q21131958-150209B8-F7A7-43F7-8C05-0D94A58740EAQ30379477-3070E6D2-CC05-41C3-942C-0EA14B7A2E9AQ30385823-01DC3856-A1A2-432E-86B8-D2AC98BC94D7Q31027559-AF5FB844-69BE-4C66-893F-DB9935FCCF7DQ33360099-FA4E2E70-4392-43C5-A7FB-D154538B3DAAQ33515698-64511A22-7B5D-489F-8395-722F3BE9E84FQ35771110-2A0C7BE8-F0BC-4B02-80D5-569D91695F0DQ36692714-190F1B2A-C285-42FF-A172-0EB902543F5BQ37354075-02C52E50-171F-4202-A71C-8F923F74CF74Q38100141-BE76450A-B5D0-4408-8524-82B3AB096DA7Q38194519-E2B95F05-2F43-4B53-AECF-7BA0C8ED12B1Q38200597-44FE1C54-FAB1-41A6-BF25-0CC64808B03EQ38667906-12E95D32-2B2B-433C-BAAB-45EC29D5E32BQ41541706-2A3285B4-AD42-436A-853F-00EF15B76C02Q41908787-6A1F84BA-B73E-4286-9A22-81ABDD924EAEQ42013940-451FEAD1-5040-4636-955F-61EDD41FA6B6Q43248262-9C0B7307-E48D-4EC2-AA6A-AC1774444D4AQ43683958-1502F41B-32E4-4A9E-B1E5-81F4FF560478Q43750152-9F886547-8665-464F-826D-DB242A7339CCQ45792036-27A0285E-E499-4E92-B914-0E4DB5DE881FQ46129119-3044BCA0-5E74-46FA-A472-E7F30C8865ABQ46306177-80A4F49E-3A3C-4524-8550-89195D2936BDQ46494661-23D61C62-F7C7-4D30-9059-E890E0C752AFQ46534171-F706633C-450D-4B00-AC3F-24BF83D7F234Q46905212-51DD7593-657C-46A9-8862-81ADBEC79CF0Q46954300-B02791F9-C486-4D11-8E1E-4C329CC153B4Q47210009-837F5E9E-9FB7-4517-BCD5-6B09CC65A2F1Q47954936-C9EDDE96-AC70-41CC-B856-F7D5003FD7DCQ48044611-7502774A-6624-4BD2-9AF8-170BB32840C0Q49887007-8756C6F3-20ED-4935-853E-ED424D526B74Q54521790-D90AD931-666B-4B73-8A01-8DA840C26546Q58577385-E8FCF774-6165-42CB-8AFA-0360D7CDB988
P2860
Autoluminescence imaging: a non-invasive tool for mapping oxidative stress.
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
Autoluminescence imaging: a non-invasive tool for mapping oxidative stress.
@ast
Autoluminescence imaging: a non-invasive tool for mapping oxidative stress.
@en
type
label
Autoluminescence imaging: a non-invasive tool for mapping oxidative stress.
@ast
Autoluminescence imaging: a non-invasive tool for mapping oxidative stress.
@en
prefLabel
Autoluminescence imaging: a non-invasive tool for mapping oxidative stress.
@ast
Autoluminescence imaging: a non-invasive tool for mapping oxidative stress.
@en
P2093
P1476
Autoluminescence imaging: a non-invasive tool for mapping oxidative stress.
@en
P2093
Bernard Genty
Christian Triantaphylidès
Michel Havaux
P304
P356
10.1016/J.TPLANTS.2006.08.001
P577
2006-09-07T00:00:00Z