Temperature responses of mesophyll conductance differ greatly between species.
about
Photosynthetic enhancement by elevated CO₂ depends on seasonal temperatures for warmed and non-warmed Eucalyptus globulus trees.A roadmap for improving the representation of photosynthesis in Earth system models.Acclimation of Biochemical and Diffusive Components of Photosynthesis in Rice, Wheat, and Maize to Heat and Water Deficit: Implications for Modeling Photosynthesis.Autumn photosynthetic decline and growth cessation in seedlings of white spruce are decoupled under warming and photoperiod manipulations.Increase in leaf temperature opens stomata and decouples net photosynthesis from stomatal conductance in Pinus taeda and Populus deltoides x nigraNitrogen Can Alleviate the Inhibition of Photosynthesis Caused by High Temperature Stress under Both Steady-State and Flecked IrradianceStrong thermal acclimation of photosynthesis in tropical and temperate wet-forest tree species: the importance of altered Rubisco content.A compendium of temperature responses of Rubisco kinetic traits: variability among and within photosynthetic groups and impacts on photosynthesis modelingRubisco Catalytic Properties and Temperature Response in Crops.Biochemical model of C3 photosynthesis applied to wheat at different temperatures.Understanding regulation of leaf internal carbon and water transport using online stable isotope techniques.Carbon dioxide and water transport through plant aquaporins.Rubisco and Rubisco Activase Play an Important Role in the Biochemical Limitations of Photosynthesis in Rice, Wheat, and Maize under High Temperature and Water Deficit.Stomatal conductance increases with rising temperature.Temperature response of bundle-sheath conductance in maize leavesModelling water use efficiency in a dynamic environment: An example using Arabidopsis thaliana.Simple generalisation of a mesophyll resistance model for various intracellular arrangements of chloroplasts and mitochondria in C3 leaves.Uncertainty in measurements of the photorespiratory CO2 compensation point and its impact on models of leaf photosynthesisShort-term thermal photosynthetic responses of C4 grasses are independent of the biochemical subtype.High light aggravates functional limitations of cucumber canopy photosynthesis under salinity.In situ temperature relationships of biochemical and stomatal controls of photosynthesis in four lowland tropical tree species.Temperature response of mesophyll conductance in three C4 species calculated with two methods: 18 O discrimination and in vitro Vpmax.Leaf hydraulic conductance and mesophyll conductance are not closely related within a single species.Effects of reduced carbonic anhydrase activity on CO2 assimilation rates in Setaria viridis: a transgenic analysis.Online CO2 and H2 O oxygen isotope fractionation allows estimation of mesophyll conductance in C4 plants, and reveals that mesophyll conductance decreases as leaves age in both C4 and C3 plants.Improved method for measuring the apparent CO2 photocompensation point resolves the impact of multiple internal conductances to CO2 to net gas exchange.Photosynthetic induction and its diffusional, carboxylation and electron transport processes as affected by CO2 partial pressure, temperature, air humidity and blue irradiance.Photosynthesis: ancient, essential, complex, diverse … and in need of improvement in a changing world.Dynamic modelling of limitations on improving leaf CO2 assimilation under fluctuating irradiance.Persistent negative temperature response of mesophyll conductance in red raspberry (Rubus idaeus L.) leaves under both high and low vapour pressure deficits: a role for abscisic acid?Do all leaf photosynthesis parameters of rice acclimate to elevated CO2 , elevated temperature, and their combination, in FACE environments?Variable Mesophyll Conductance among Soybean Cultivars Sets a Tradeoff between Photosynthesis and Water-Use-Efficiency.Coupled response of stomatal and mesophyll conductance to light enhances photosynthesis of shade leaves under sunflecks.The sensitivity of photosynthesis to O2 and CO2 concentration identifies strong Rubisco control above the thermal optimum.A novel mechanistic interpretation of instantaneous temperature responses of leaf net photosynthesis.Association between water and carbon dioxide transport in leaf plasma membranes: assessing the role of aquaporins.Genetic control of mesophyll conductance in common wheat.Canola Responses to Drought, Heat, and Combined Stress: Shared and Specific Effects on Carbon Assimilation, Seed Yield, and Oil CompositionDiffusion of CO across the Mesophyll-Bundle Sheath Cell Interface in a C Plant with Genetically Reduced PEP Carboxylase ActivityProteomics Analysis Reveals Non-Controlled Activation of Photosynthesis and Protein Synthesis in a Rice Mutant under High Temperature and Elevated CO₂ Conditions
P2860
Q31010242-D8D5D90A-AD62-49F0-B9AD-4ACD6F7A3D13Q31144985-A2C325B4-05BD-4409-897F-2F843B653B12Q31147087-BEBDBA3D-775E-4763-B636-2A3E2B8558EDQ31155380-9383B95B-484C-4F8A-ACAC-A1270F7EFF83Q33727370-024AB394-EC8C-4DFE-954E-94134EF7703FQ33766153-280B5816-07FD-4755-BE11-CFF7B40A4265Q38793909-24E1B8E2-DA3F-4D97-AE0E-6D248ED7110AQ38842574-3433789D-6844-4C76-AD16-13F24437F158Q38850091-F2D2DFAE-E8D3-403F-96DA-F4AE528958DAQ38880175-D930BF12-D21D-4078-A728-100F5DD8EBF0Q38960222-8DEFF506-EC7C-4056-85EB-9D22A3BD3DC3Q38980365-624D91CD-B4F0-4FFA-A258-3937E11F7939Q39348990-23B04AB8-7251-484A-994D-24D65CA27E3FQ40493536-7D65EBA1-165E-4F5E-81E8-0BD0FE979FEBQ41191180-7500618D-8653-4677-8993-C8A99C0CDE64Q41197976-A342D591-B1D5-4283-975C-6B7F23BCDA10Q41891066-16047FBC-715B-4150-91D5-29229C27E2ACQ42246172-145595CE-5937-4D09-996F-6EE06D0FA1B5Q46281330-23506436-9EEB-4F43-AD03-B3146F24B839Q46286795-97B4CB3A-EFF4-48B3-ABC4-AEA7E3569E6AQ46304565-DEDEF1F3-3CFD-438A-9488-88797596D56FQ46450266-104E7FEB-F34D-4D1B-860B-B0FE52990BACQ46457949-D35ED0BE-F79A-4E12-A62D-1DA461E72227Q46482065-4F7DC09C-25F9-4ADD-BEAF-6C5F917D520DQ46609568-2F77AA64-6846-41F5-A9A4-378E3F18B7A6Q46735280-5EB08276-1013-4C36-B5EB-581777FFD156Q47118442-A3A83BBB-0E3E-4760-BCE2-B1941A55D570Q47253653-0879F7F7-30B4-4AC4-8A4B-848246F7D52EQ47575562-068034AC-50C2-48A2-9D95-DEBF4F6E5E95Q47854861-E073497B-75B9-4802-B773-E58B4775AC25Q47873556-033B1BC5-5DF6-469C-A81D-2EFB5DB967B3Q48152938-32874CA2-5BC2-4784-B888-129ED1D0EE47Q48308790-D4DA3294-8FEF-409B-B1B7-A9651EEB8C41Q50279104-0F12916C-BB8E-4E3C-B1AE-C45516000D60Q50639394-200E9227-8DF1-4533-A5B5-0D3D9F11EE26Q51515519-BA4E8FE3-EEC0-4026-A5C2-FA5DBCE95D55Q53210480-696671C9-45A4-4106-8FB5-B829EA769960Q57071019-1877D2A6-37D3-4AA7-849E-591CC42C0404Q57400496-5B4A3407-0068-4BEC-B4E2-FDB745F30C0EQ58758238-C4A3202E-6192-487B-9A82-8489E056A354
P2860
Temperature responses of mesophyll conductance differ greatly between species.
description
2014 nî lūn-bûn
@nan
2014 թուականի Հոկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2014 թվականի հոտեմբերին 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
Temperature responses of mesophyll conductance differ greatly between species.
@ast
Temperature responses of mesophyll conductance differ greatly between species.
@en
type
label
Temperature responses of mesophyll conductance differ greatly between species.
@ast
Temperature responses of mesophyll conductance differ greatly between species.
@en
prefLabel
Temperature responses of mesophyll conductance differ greatly between species.
@ast
Temperature responses of mesophyll conductance differ greatly between species.
@en
P2860
P356
P1476
Temperature responses of mesophyll conductance differ greatly between species.
@en
P2093
John R Evans
P2860
P304
P356
10.1111/PCE.12449
P577
2014-10-21T00:00:00Z