Significance of the V-type ATPase for the adaptation to stressful growth conditions and its regulation on the molecular and biochemical level.
about
Mechanism of salinity tolerance in plants: physiological, biochemical, and molecular characterizationSubcellular distribution of the V-ATPase complex in plant cells, and in vivo localisation of the 100 kDa subunit VHA-a within the complexResponses of the Emiliania huxleyi proteome to ocean acidificationTranscriptomic analysis of Chinese bayberry (Myrica rubra) fruit development and ripening using RNA-Seq.Molecular response of Sargassum vulgare to acidification at volcanic CO2 vents: insights from de novo transcriptomic analysis.Genetic control of functional traits related to photosynthesis and water use efficiency in Pinus pinaster Ait. drought response: integration of genome annotation, allele association and QTL detection for candidate gene identification.A proteomics study of the mung bean epicotyl regulated by brassinosteroids under conditions of chilling stress.Differential expression of vacuolar H+-ATPase subunit c genes in tissues active in membrane trafficking and their roles in plant growth as revealed by RNAi.Membrane-bound guaiacol peroxidases from maize (Zea mays L.) roots are regulated by methyl jasmonate, salicylic acid, and pathogen elicitors.A proteomic study of the response to salinity and drought stress in an introgression strain of bread wheat.Genome-wide transcriptome and functional analysis of two contrasting genotypes reveals key genes for cadmium tolerance in barleyRegulation of transport processes across the tonoplast.The wheat E subunit of V-type H+-ATPase is involved in the plant response to osmotic stressEnhanced expression of vacuolar H+-ATPase subunit E in the roots is associated with the adaptation of Broussonetia papyrifera to salt stress.Suppression Subtractive Hybridization Analysis of Genes Regulated by Application of Exogenous Abscisic Acid in Pepper Plant (Capsicum annuum L.) Leaves under Chilling Stress.Novel metabolic attributes of the genus cyanothece, comprising a group of unicellular nitrogen-fixing Cyanothece.DNA microarray revealed and RNAi plants confirmed key genes conferring low Cd accumulation in barley grains.454 Pyrosequencing of Olive (Olea europaea L.) Transcriptome in Response to SalinityTranscriptome profiling of Kentucky bluegrass (Poa pratensis L.) accessions in response to salt stressArabidopsis vacuolar H+-ATPase (V-ATPase) B subunits are involved in actin cytoskeleton remodeling via binding to, bundling, and stabilizing F-actin.Overexpression of ThVHAc1 and its potential upstream regulator, ThWRKY7, improved plant tolerance of Cadmium stress.Comparative proteomic analysis of Puccinellia tenuiflora leaves under Na2CO3 stress.Plant proton pumps.Low Temperature and Short-Term High-CO2 Treatment in Postharvest Storage of Table Grapes at Two Maturity Stages: Effects on Transcriptome Profiling.Na(+) compartmentalization related to salinity stress tolerance in upland cotton (Gossypium hirsutum) seedlings.Regulation by salt of vacuolar H+-ATPase and H+-pyrophosphatase activities and Na+/H+ exchange.Gibberellins and abscisic acid signal crosstalk: living and developing under unfavorable conditions.Membrane transporters mediating root signalling and adaptive responses to oxygen deprivation and soil flooding.Comparative Analysis of the Chrysanthemum Leaf Transcript Profiling in Response to Salt Stress.The SNF1-type serine-threonine protein kinase SAPK4 regulates stress-responsive gene expression in rice.Waterlogging and submergence stress: affects and acclimation.Connecting Salt Stress Signalling Pathways with Salinity Induced Changes in Mitochondrial Metabolic Processes in C3 Plants.Comparative protein profiles of Butea superba tubers under seasonal changes.Revealing the roles of GORK channels and NADPH oxidase in acclimation to hypoxia in Arabidopsis.The Role of pH Regulation in Cancer Progression.Proteomics analysis of sensitive and tolerant barley genotypes under drought stress.OsbZIP71, a bZIP transcription factor, confers salinity and drought tolerance in rice.V-ATPase dysfunction under excess zinc inhibits Arabidopsis cell expansion.Characterization of seed germination, seedling growth, and associated metabolic responses of Brassica juncea L. cultivars to elevated nickel concentrations.Rootstock-scion interaction affecting citrus response to CTV infection: a proteomic view.
P2860
Q21284668-2AEA9B7E-66E5-4EF5-A019-4608A856E2D0Q24805462-600431F6-14AE-49A7-8A9D-C9010A556911Q28486168-3674C9B2-1A27-4CAD-8A53-8ACEB7B506EFQ30520648-B75E8605-40DC-4034-9224-962204EB5F87Q31157703-016D6630-D256-4BB7-BF2B-208B8805BC5BQ31165162-0E969919-CCBF-44EE-B5B7-A0AC8CEF3C89Q33250485-B31A4714-B1F0-4BB0-9607-40E0282FE8B0Q33339884-A2DF4CE2-9F76-42ED-B010-22E09BEC701DQ33621697-A2355EEE-8E06-4598-ACDD-C78372AD0E5FQ33628858-167E9457-4C06-4485-9B6A-1BE013D181B1Q33984599-85B80C4C-45BB-4DC9-A759-57F753E1883CQ34159621-12BDED86-FEA7-41AB-8A00-0C452D142E9EQ34358629-87EBE44A-F361-45C5-8C16-9B0511108926Q34469380-BAF63F13-22CD-49D0-BA5B-1A55F6B2FD96Q34794176-F131AADF-BB64-429A-A003-403D26A8741BQ35275857-558ECDAF-2FBF-4B69-AA15-59371E5BCA6CQ35821813-5652CAEF-2B65-4FCC-83F2-F59E68EEA287Q35843801-C69631B1-8958-494B-A1F2-12A11911A6ECQ35892148-F43602CB-98B6-425A-BB88-22CF7685FC5EQ36003645-7CAFE4A7-1ACD-44A5-90E5-1041D0A217B7Q36442621-A3DEEEFF-CD05-47C8-B466-49C57F18C8F3Q36590113-8C68FF5D-3A08-4C20-A258-60346E49A8DDQ36782393-9EC346BE-E8F9-42E5-B9E7-00A1217DC19CQ37088782-BEBC9B04-BDB1-4FED-966E-D864697DBC22Q37307392-55978C9F-17AA-45F6-9F8B-68EAABFD9690Q37612731-4560F14C-6956-4FFE-97B7-FD0311D014D8Q38092696-2FA692AF-92F0-45AA-B32E-EF4926BA1A12Q38201139-B1192405-06D1-4635-A41F-006E66F5302EQ38444540-2D99D200-799B-420B-A6C0-F3C92A5B0313Q38525379-1D53400A-171A-45FD-9D5D-767C35020428Q38547612-844E4BDE-F0DB-4DFD-9294-30D776A204EAQ38652166-043BC620-9CD5-44D8-B72D-5C0AA9F690B1Q38865032-3688CECB-BCB9-4B32-A34A-295A6056ADD3Q38879737-A5DEEBCB-C111-4251-AF16-58B495587088Q38936259-E4234CFB-28B7-4424-9896-0F142044D8B3Q39124422-92B32D56-4F8A-4340-AD61-8821EEFC2078Q39183210-042FFF32-76F0-46BE-8AC5-090B24AC797BQ40391961-A8D21CAB-C051-46FA-A551-5027D09DBC0BQ40888957-D5205AA6-1AB1-4B08-A43A-484A425081C4Q40955888-3805B3A4-C3C4-4961-AFDE-97ED169BBB67
P2860
Significance of the V-type ATPase for the adaptation to stressful growth conditions and its regulation on the molecular and biochemical level.
description
2001 nî lūn-bûn
@nan
2001 թուականի Հոկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2001 թվականի հոտեմբերին հրատարակված գիտական հոդված
@hy
2001年の論文
@ja
2001年論文
@yue
2001年論文
@zh-hant
2001年論文
@zh-hk
2001年論文
@zh-mo
2001年論文
@zh-tw
2001年论文
@wuu
name
Significance of the V-type ATP ...... lecular and biochemical level.
@ast
Significance of the V-type ATP ...... lecular and biochemical level.
@en
Significance of the V-type ATP ...... lecular and biochemical level.
@nl
type
label
Significance of the V-type ATP ...... lecular and biochemical level.
@ast
Significance of the V-type ATP ...... lecular and biochemical level.
@en
Significance of the V-type ATP ...... lecular and biochemical level.
@nl
prefLabel
Significance of the V-type ATP ...... lecular and biochemical level.
@ast
Significance of the V-type ATP ...... lecular and biochemical level.
@en
Significance of the V-type ATP ...... lecular and biochemical level.
@nl
P2093
P2860
P356
P1476
Significance of the V-type ATP ...... lecular and biochemical level.
@en
P2093
Chardonnens AN
Golldack D
Tavakoli N
P2860
P304
P356
10.1093/JEXBOT/52.363.1969
P577
2001-10-01T00:00:00Z