about
Breeding for plant heat tolerance at vegetative and reproductive stagesApplication of genomics-assisted breeding for generation of climate resilient crops: progress and prospectsRubisco activity and regulation as targets for crop improvementPlant tolerance to high temperature in a changing environment: scientific fundamentals and production of heat stress-tolerant cropsEffects of long-term individual and combined water and temperature stress on the growth of rice, wheat and maize: relationship with morphological and physiological acclimation.Does long-term cultivation of saplings under elevated CO2 concentration influence their photosynthetic response to temperature?Acclimation of Biochemical and Diffusive Components of Photosynthesis in Rice, Wheat, and Maize to Heat and Water Deficit: Implications for Modeling Photosynthesis.Over-expressing the C(3) photosynthesis cycle enzyme Sedoheptulose-1-7 Bisphosphatase improves photosynthetic carbon gain and yield under fully open air CO(2) fumigation (FACE).Observed changes in winter wheat phenology in the North China Plain for 1981-2009.Global warming can negate the expected CO2 stimulation in photosynthesis and productivity for soybean grown in the Midwestern United States.The metabolic basis of pollen thermo-tolerance: perspectives for breeding.Responses of plant biomass, photosynthesis and lipid peroxidation to warming and precipitation change in two dominant species (Stipa grandis and Leymus chinensis) from North China Grasslands.Chloroplast transformation for engineering of photosynthesis.Current methods for estimating the rate of photorespiration in leaves.Changes to DNA methylation and homologous recombination frequency in the progeny of stressed plants.Enhancing C3 photosynthesis: an outlook on feasible interventions for crop improvement.Temperature responses of the Rubisco maximum carboxylase activity across domains of life: phylogenetic signals, trade-offs, and importance for carbon gain.Photosynthetic energy conversion efficiency: setting a baseline for gauging future improvements in important food and biofuel crops.The redox control of photorespiration: from biochemical and physiological aspects to biotechnological considerations.Photosynthesis, Light Use Efficiency, and Yield of Reduced-Chlorophyll Soybean Mutants in Field Conditions.From metabolome to phenotype: GC-MS metabolomics of developing mutant barley seeds reveals effects of growth, temperature and genotype.Proteomics of rice grain under high temperature stress.Genotypic variation in spike fertility traits and ovary size as determinants of floret and grain survival rate in wheat.Temperature dependence of in vitro Rubisco kinetics in species of Flaveria with different photosynthetic mechanisms.Optimizing antenna size to maximize photosynthetic efficiency.Mono- and sesquiterpene release from tomato (Solanum lycopersicum) leaves upon mild and severe heat stress and through recovery: from gene expression to emission responses.Impacts of a nuclear war in South Asia on soybean and maize production in the Midwest United StatesThe global plant council: Increasing the impact of plant research to meet global challengesEffect of climate change on field crop production in California’s Central ValleyDown-regulation of Rubisco activity under combined increases of CO2 and temperature minimized by changes in Rubisco kcat in wheat
P2860
Q26766197-ADB9D58D-0700-46A9-82C2-D0D9032B6389Q26795958-2BABAE81-6871-4600-B689-6D5FF5609FC7Q26862853-3BD15B12-EF56-4F7D-BF8A-206F632AFEE3Q30659257-7FBA8DE7-E990-401C-8D0F-64BE7C2F0969Q30864239-9C864ABC-CEDE-4B20-A0D9-0ECE447A8F25Q30926294-A7F159F6-96B4-4CB1-9FB6-6E178F167D90Q31147087-5BFDBBB9-C5D3-483E-BF6E-0CC9C35859E3Q34007909-6B6CBCA7-FFD5-462E-9C5E-3D3384AED3D4Q34259344-8CB6CCE1-A997-4202-BD25-31A355C1477EQ34628206-707B476F-5BEB-4F84-B115-28F67C5D0538Q34785730-4216BF86-E54A-4724-B7F2-1FA7154ACD08Q35942553-529E3AE7-991B-4CA7-9B6B-1E634A7E1A46Q38060698-1AE767BE-6C27-4507-830F-9BEDB6BC0121Q38062947-B70CFCB3-A4FA-4320-96CF-9A9827AEDE4FQ38084747-F2BE81C6-0D8D-4D61-AC50-DB7BD944FF68Q38246666-9F341157-FEDA-48E9-B6D8-47E593449EADQ38291048-04DC895B-E3AE-48D0-A2E0-ABD01B6CA528Q38398702-59F4E714-F8AF-42FE-8920-A49C1629E70EQ38704851-5FC50B4E-D738-4D61-893C-582ACD8A328CQ39470303-01E53FF3-02D6-4DBF-8F7D-952E18C295FAQ41421230-1075C1B8-BAD4-4FB8-A77D-30A165D93311Q41545383-A9234BEE-F647-4745-BC51-7C3B9E892EC8Q42275233-BE1A8058-559C-4FAC-A0A9-E3B7058E5EB0Q46775160-3F3501DF-BF40-4451-9854-0BA84E2C7CC2Q47405405-97A460DA-9D18-4F9C-92EC-5818ED13B405Q49723640-18866D2B-BD02-4EDD-A12D-3F3226CD9554Q57275460-7C3F0001-94E1-412D-94EA-366B54C3ECB0Q58057145-3CE5EAF9-1BD4-4B8C-B7F1-913D5F5F37E1Q58241691-B2D3803B-45F2-4037-88C7-D2FDCFDD0EC6Q59000075-57C1A922-F4F5-4880-946B-6D3C96B89AF2
P2860
description
2010 nî lūn-bûn
@nan
2010 թուականի Հոկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի հոտեմբերին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
name
How do we improve crop production in a warming world?
@ast
How do we improve crop production in a warming world?
@en
type
label
How do we improve crop production in a warming world?
@ast
How do we improve crop production in a warming world?
@en
prefLabel
How do we improve crop production in a warming world?
@ast
How do we improve crop production in a warming world?
@en
P2860
P356
P1433
P1476
How do we improve crop production in a warming world?
@en
P2093
Donald R Ort
Elizabeth A Ainsworth
P2860
P304
P356
10.1104/PP.110.161349
P407
P577
2010-10-01T00:00:00Z