Simultaneous application of heat, drought, and virus to Arabidopsis plants reveals significant shifts in signaling networks.
about
Shared and unique responses of plants to multiple individual stresses and stress combinations: physiological and molecular mechanismsToward a systems understanding of plant-microbe interactionsDrought Stress Predominantly Endures Arabidopsis thaliana to Pseudomonas syringae InfectionSenescence, Stress, and Reactive Oxygen SpeciesCentral Metabolic Responses to Ozone and Herbivory Affect Photosynthesis and Stomatal ClosureTranscriptome responses to temperature, water availability and photoperiod are conserved among mature trees of two divergent Douglas-fir provenances from a coastal and an interior habitatMembrane lipid remodelling of Meconopsis racemosa after its introduction into lowlands from an alpine environmentGene expression analysis of rocket salad under pre-harvest and postharvest stresses: A transcriptomic resource for Diplotaxis tenuifolia.Responses of In vitro-Grown Plantlets (Vitis vinifera) to Grapevine leafroll-Associated Virus-3 and PEG-Induced Drought Stress.Metabolic and transcriptomic signatures of rice floral organs reveal sugar starvation as a factor in reproductive failure under heat and drought stress.High Temperature, High Ambient CO₂ Affect the Interactions between Three Positive-Sense RNA Viruses and a Compatible Host Differentially, but not Their Silencing Suppression Efficiencies.A Proteome Translocation Response to Complex Desert Stress Environments in Perennial Phragmites Sympatric Ecotypes with Contrasting Water AvailabilityEnhancing crop resilience to combined abiotic and biotic stress through the dissection of physiological and molecular crosstalk.LSU network hubs integrate abiotic and biotic stress responses via interaction with the superoxide dismutase FSD2Global profiling of phytohormone dynamics during combined drought and pathogen stress in Arabidopsis thaliana reveals ABA and JA as major regulators.Alfalfa Cellulose synthase gene expression under abiotic stress: a Hitchhiker's guide to RT-qPCR normalizationIn silico selection of Arabidopsis thaliana ecotypes with enhanced stress tolerance.A novel system for evaluating drought-cold tolerance of grapevines using chlorophyll fluorescence.Design and construction of an inexpensive homemade plant growth chamber.Priming and memory of stress responses in organisms lacking a nervous system.Analysis of Cell Wall-Related Genes in Organs of Medicago sativa L. under Different Abiotic StressesTemperature expression patterns of genes and their coexpression with LncRNAs revealed by RNA-Seq in non-heading Chinese cabbageß-amylase1 mutant Arabidopsis plants show improved drought tolerance due to reduced starch breakdown in guard cells.Transcriptome Analysis of Sunflower Genotypes with Contrasting Oxidative Stress Tolerance Reveals Individual- and Combined- Biotic and Abiotic Stress Tolerance Mechanisms.Transcriptomic comparison between two Vitis vinifera L. varieties (Trincadeira and Touriga Nacional) in abiotic stress conditionsNAC transcription factors in plant multiple abiotic stress responses: progress and prospectsEffect of temperature on the pathogenesis, accumulation of viral and satellite RNAs and on plant proteome in peanut stunt virus and satellite RNA-infected plants.Back into the wild-Apply untapped genetic diversity of wild relatives for crop improvementDrought stress had a predominant effect over heat stress on three tomato cultivars subjected to combined stress.Comparative transcriptomic analysis reveals the roles of overlapping heat-/drought-responsive genes in poplars exposed to high temperature and drought.Unique Physiological and Transcriptional Shifts under Combinations of Salinity, Drought, and Heat.Differences and commonalities of plant responses to single and combined stresses.Water deficit enhances the transmission of plant viruses by insect vectors.Tomato yellow leaf curl virus infection mitigates the heat stress response of plants grown at high temperaturesSelection of suitable reference genes for assessing gene expression in pearl millet under different abiotic stresses and their combinationsPepper CabZIP63 acts as a positive regulator during Ralstonia solanacearum or high temperature-high humidity challenge in a positive feedback loop with CaWRKY40.Two Novel DNAs That Enhance Symptoms and Overcome CMD2 Resistance to Cassava Mosaic DiseaseGlobal Transcriptional Analysis Reveals Unique and Shared Responses in Arabidopsis thaliana Exposed to Combined Drought and Pathogen Stress.Understanding the Impact of Drought on Foliar and Xylem Invading Bacterial Pathogen Stress in ChickpeaCoronatine Facilitates Pseudomonas syringae Infection of Arabidopsis Leaves at Night.
P2860
Q26781193-0A6D0704-50A9-46D9-A943-8FF7F4553D1AQ26865799-56B061A2-08CB-43B7-B4A2-17E14050E492Q27306958-7DE6BE9A-3F3A-48EC-8019-22701CFB78F8Q28080667-A2B1572E-312F-4D3E-8E05-A6F4001E37E9Q28596123-1EBBC565-18C8-4930-AAFF-0798B9C3CEFFQ28596926-45F27CE1-1CD3-4127-A166-2F5C07D43EF5Q28656029-F808498B-4837-41A1-8DBD-8CB23E68E1A3Q30100959-FE4C7059-6C43-4A49-A73F-14B50D7FDB8BQ30383261-20088A57-C2D8-4AF6-B911-FBFEA83C026AQ30920535-283D06C9-F131-4FE2-8889-9C50199E92A4Q30990366-A91DE315-FD7A-41F3-923C-C8BAB1AE5491Q33559408-128842BD-88C4-4998-9909-8F240B88E7F8Q33657895-969A08EF-0F0F-4F1F-B850-32AACEA49B52Q33719578-C7F24326-8BD5-4FFD-96B5-66C5DCBF4CF0Q33822573-291D3F7A-C85E-4815-9473-DD917DFE811FQ33989428-0DEACB85-196F-428F-ABE3-3EC9AEA1857CQ34983330-ACDE9FA8-2AB7-4674-99F9-02D6EADCA922Q35201059-8A86CE23-C5A3-4912-BC15-D411E20DF1C3Q35627939-2BC89BC3-5D28-4F2B-892D-CCDCC29B6A56Q35750802-C84339EF-1D1D-40FF-9EC3-FE0194985EE3Q35902604-52C3304B-56A8-4962-B9F0-47EFDF5D9FEDQ35996650-2ABC0FDA-9D13-43AD-A25E-A37335785FA4Q36051644-1710773F-6EC0-4DE9-9D54-3E4C9DCC73E2Q36055294-46BB3424-57F6-424F-884E-47E0DDF7B345Q36161710-44BE8A04-C365-4F70-8AA9-BE6FA6F34A95Q36221342-3967EBF0-4317-457C-ABAF-53BB3F221858Q36221711-E2241524-98B6-40FD-9D5F-95F0E2CF5AC1Q36236074-CB063200-BF2D-4B39-8D7A-4540283FF31DQ36260110-3D982BB4-6959-4603-BAE6-62CA92B960EDQ36289258-793338EA-3AFE-4CCC-9793-C481AD075894Q36313466-E69427AD-FD32-4244-88CD-F2A97A51620FQ36332665-C132D12D-7DE5-4D3D-9AA2-8BF795E34D08Q36361840-D86B8C23-51EC-4828-A000-0759A3DDAF03Q36500278-E56FB490-EB43-432B-9AF6-25F6CE2E7435Q36682194-7FA0BC8A-D24B-4FDC-AC8C-58B9B9C5CE9AQ36733454-BAE9D7FF-7238-4399-B357-CA758DE48684Q36736430-A2FC8740-0524-475F-9C44-B55BE4A5C7D7Q36930462-9DB11F18-E922-4FE7-9675-6D5F0676C580Q37023037-EEDE6F4A-3DBD-4EBD-8A49-D013C9716A30Q37024085-83A40EB2-2FD9-4388-B590-8E83CFA2C9C9
P2860
Simultaneous application of heat, drought, and virus to Arabidopsis plants reveals significant shifts in signaling networks.
description
2013 nî lūn-bûn
@nan
2013 թուականի Յունիսին հրատարակուած գիտական յօդուած
@hyw
2013 թվականի հունիսին հրատարակված գիտական հոդված
@hy
2013年の論文
@ja
2013年論文
@yue
2013年論文
@zh-hant
2013年論文
@zh-hk
2013年論文
@zh-mo
2013年論文
@zh-tw
2013年论文
@wuu
name
Simultaneous application of he ...... shifts in signaling networks.
@ast
Simultaneous application of he ...... shifts in signaling networks.
@en
type
label
Simultaneous application of he ...... shifts in signaling networks.
@ast
Simultaneous application of he ...... shifts in signaling networks.
@en
prefLabel
Simultaneous application of he ...... shifts in signaling networks.
@ast
Simultaneous application of he ...... shifts in signaling networks.
@en
P2860
P356
P1433
P1476
Simultaneous application of he ...... shifts in signaling networks.
@en
P2093
Christian Maximilian Prasch
Uwe Sonnewald
P2860
P304
P356
10.1104/PP.113.221044
P407
P577
2013-06-10T00:00:00Z