A putative role for TIP and PIP aquaporins in dynamics of leaf hydraulic and stomatal conductances in grapevine under water stress and re-watering.
about
Aquaporins: highly regulated channels controlling plant water relationsMongolian Almond (Prunus mongolica Maxim): The Morpho-Physiological, Biochemical and Transcriptomic Response to Drought StressIncreasing leaf hydraulic conductance with transpiration rate minimizes the water potential drawdown from stem to leaf.Physiological and genomic basis of mechanical-functional trade-off in plant vasculatureCharacterization and Regulation of Aquaporin Genes of Sorghum [Sorghum bicolor (L.) Moench] in Response to Waterlogging StressExploring three PIPs and three TIPs of grapevine for transport of water and atypical substrates through heterologous expression in aqy-null yeast.Metabolite profiling and network analysis reveal coordinated changes in grapevine water stress response.Overexpression of the CaTIP1-1 pepper gene in tobacco enhances resistance to osmotic stressesLeaf hydraulic conductance is coordinated with leaf morpho-anatomical traits and nitrogen status in the genus Oryza.The role of water channel proteins in facilitating recovery of leaf hydraulic conductance from water stress in Populus trichocarpa.The Role of Aquaporins in pH-Dependent Germination of Rhizopus delemar Spores.Transcriptional Responses in Root and Leaf of Prunus persica under Drought Stress Using RNA Sequencing.Regulation of leaf hydraulics: from molecular to whole plant levels.Threshold response of mesophyll CO2 conductance to leaf hydraulics in highly transpiring hybrid poplar clones exposed to soil drying.Role of aquaporins in determining transpiration and photosynthesis in water-stressed plants: crop water-use efficiency, growth and yield.Genotypic variation in tolerance to drought stress is highly coordinated with hydraulic conductivity-photosynthesis interplay and aquaporin expression in field-grown mulberry (Morus spp.).Aquaporins and plant transpiration.The functional role of xylem parenchyma cells and aquaporins during recovery from severe water stress.Genetic variation in a grapevine progeny (Vitis vinifera L. cvs Grenache×Syrah) reveals inconsistencies between maintenance of daytime leaf water potential and response of transpiration rate under drought.Outside-Xylem Vulnerability, Not Xylem Embolism, Controls Leaf Hydraulic Decline during Dehydration.Aquaporin gene expression and physiological responses of Robinia pseudoacacia L. to the mycorrhizal fungus Rhizophagus irregularis and drought stress.Drought response of mesophyll conductance in forest understory species--impacts on water-use efficiency and interactions with leaf water movement.Factors influencing stomatal conductance in response to water availability in grapevine: a meta-analysis.Down-regulation of plasma intrinsic protein1 aquaporin in poplar trees is detrimental to recovery from embolism.Plasticity of vulnerability to leaf hydraulic dysfunction during acclimation to drought in grapevines: an osmotic-mediated process.Abiotic stresses influence the transcript abundance of PIP and TIP aquaporins in Festuca species.Greater efficiency of water use in poplar clones having a delayed response of mesophyll conductance to drought.Relationships between stomatal behavior, xylem vulnerability to cavitation and leaf water relations in two cultivars of Vitis vinifera.Role of hydraulic and chemical signals in leaves, stems and roots in the stomatal behaviour of olive trees under water stress and recovery conditions.Functional characterization of an aquaporin from a microsporidium, Nosema bombycis.Leaf aquaporin transcript abundance in peanut genotypes diverging in expression of the limited-transpiration trait when subjected to differing vapor pressure deficits and aquaporin inhibitors.Regulation of photosynthesis and stomatal and mesophyll conductance under water stress and recovery in olive trees: correlation with gene expression of carbonic anhydrase and aquaporins.Water Balance, Hormone Homeostasis, and Sugar Signaling Are All Involved in Tomato Resistance to Tomato Yellow Leaf Curl Virus.A Comparison of Petiole Hydraulics and Aquaporin Expression in an Anisohydric and Isohydric Cultivar of Grapevine in Response to Water-Stress Induced Cavitation.The causes and consequences of leaf hydraulic decline with dehydration.Abscisic Acid Down-Regulates Hydraulic Conductance of Grapevine Leaves in Isohydric Genotypes Only.Aquaporin Expression and Water Transport Pathways inside Leaves Are Affected by Nitrogen Supply through Transpiration in Rice Plants.Dissecting the rootstock control of scion transpiration using model-assisted analyses in grapevine.Rapid shoot-to-root signalling regulates root hydraulic conductance via aquaporins.Stomatal Biology of CAM Plants.
P2860
Q26864220-047F965A-0548-4FCA-BC0F-2C9BB0F7E47DQ28546546-097473BA-1BA9-4C30-8DF7-37A46C369839Q28649468-698D5FC0-6BB8-42F5-ABD4-B9B9454494A2Q28659204-57BA5352-C6DC-47EA-9EAE-79663D10C405Q33736429-C05D3932-A2D3-4E6B-808D-BD0056750C60Q34027509-E273CB24-8E14-427D-B99E-29FB53CDE711Q34477974-B2A03826-841A-4F37-8ED6-88833DA9DBAEQ34685270-5225C7C2-0E55-4FDE-89F4-50621184E9DBQ35063413-92991A5D-F762-4A2D-9221-28B056CB3F37Q35432965-C6B1B982-DE93-4F19-B235-E9B6C19CDD53Q35951232-C1BE6437-4413-4844-8FB8-FB423DFDCCD6Q36216902-4A182913-B222-4D82-9B00-615282A5CEC3Q37011290-B72943BB-5437-4509-90F8-E9E6BBFDA0DEQ37524670-05952ED0-EE46-4670-85E0-C732317F9347Q38231314-831DEFFF-7D5D-4968-88EE-E1AB158E1E46Q38716890-574C2BBB-66B6-46EC-9B87-B1AFC6FDE4BDQ38920315-9617E5AB-ED12-4863-A64A-37532121508AQ38954358-C336D468-1064-4661-84C4-9EB890297330Q38954713-85587291-9B2E-4DF3-B812-62DE89D68A6FQ39042154-AC1CCC2E-54AE-44A0-BE98-403E90F42D67Q39060883-BC9119A8-DA4C-4D68-9712-02EC1E1CAED9Q39075374-2D3C7D13-ABA6-4965-9810-A2458464397DQ39177589-A3B8525B-42C2-4FFF-B1B6-C2FB9006A47FQ39211172-5C8858A6-CFA8-4ECB-BCAB-1F053AEF27AEQ39220348-7AE6C023-A486-4AA8-A2EB-17DD2566D41DQ39344372-9542DF4A-77CB-4173-986F-5465F672382CQ39523943-2BE50D6F-269B-4F70-B615-CC9B478A66D3Q39528399-34711479-D5CB-4FB2-B20F-06348BF4F4D5Q39530328-BB2AEBF7-6104-46FA-B2B0-6F519612B641Q40117037-6A263757-B11D-4A16-BC12-204BFD894C56Q40611955-56A74FA6-469F-4CF4-9F2F-F561BF25317CQ41237612-018A5E1F-3D48-4DD9-8087-E5981680ABF4Q42208632-3016345C-E0BF-4804-8351-231F69DE54B6Q43834385-F8F05A68-F323-439D-BDC4-E3FE44F82AE8Q46125766-76241924-9DEF-4445-A1C1-EE70841D87B1Q46308085-7BBA06D4-96E0-4BB6-92E7-9A3150FEF223Q47714734-95DB6AA3-9C83-446A-8F9F-8586037AD768Q47760326-750408E4-2536-4B70-9321-953A8E520B2FQ47829127-D0B88D32-480D-4C34-818C-E87A308B0756Q48189090-79C72615-2674-4E0D-AFB9-275A7448A972
P2860
A putative role for TIP and PIP aquaporins in dynamics of leaf hydraulic and stomatal conductances in grapevine under water stress and re-watering.
description
2012 nî lūn-bûn
@nan
2012年の論文
@ja
2012年学术文章
@wuu
2012年学术文章
@zh
2012年学术文章
@zh-cn
2012年学术文章
@zh-hans
2012年学术文章
@zh-my
2012年学术文章
@zh-sg
2012年學術文章
@yue
2012年學術文章
@zh-hant
name
A putative role for TIP and PI ...... water stress and re-watering.
@en
A putative role for TIP and PI ...... water stress and re-watering.
@nl
type
label
A putative role for TIP and PI ...... water stress and re-watering.
@en
A putative role for TIP and PI ...... water stress and re-watering.
@nl
prefLabel
A putative role for TIP and PI ...... water stress and re-watering.
@en
A putative role for TIP and PI ...... water stress and re-watering.
@nl
P2860
P50
P356
P1476
A putative role for TIP and PI ...... r water stress and re-watering
@en
P2093
Hipolito Medrano
P2860
P304
P356
10.1111/PCE.12019
P577
2012-11-01T00:00:00Z