Using C4 photosynthesis to increase the yield of rice-rationale and feasibility.
about
Phenotypic landscape inference reveals multiple evolutionary paths to C4 photosynthesisSetaria viridis: a model for C4 photosynthesisEvolutionary context for understanding and manipulating plant responses to past, present and future atmospheric [CO2Bundle sheath suberization in grass leaves: multiple barriers to characterizationGenetics-based dynamic systems model of canopy photosynthesis: the key to improve light and resource use efficiencies for cropsModeling Rice Metabolism: From Elucidating Environmental Effects on Cellular Phenotype to Guiding Crop ImprovementTransgenic Rice Expressing Ictb and FBP/Sbpase Derived from Cyanobacteria Exhibits Enhanced Photosynthesis and Mesophyll Conductance to CO2Elements required for an efficient NADP-malic enzyme type C4 photosynthesisAtmospheric carbon dioxide: a driver of photosynthetic eukaryote evolution for over a billion years?Transit peptide elements mediate selective protein targeting to two different types of chloroplasts in the single-cell C4 species Bienertia sinuspersiciPossible changes to arable crop yields by 2050.Genome-wide transcript analysis of early maize leaf development reveals gene cohorts associated with the differentiation of C4 Kranz anatomy.Combined Chlorophyll Fluorescence and Transcriptomic Analysis Identifies the P3/P4 Transition as a Key Stage in Rice Leaf Photosynthetic Development.Identification and characterization of miRNAs in two closely related C4 and C3 species of Cleome by high-throughput sequencingTowards an integrative model of C4 photosynthetic subtypes: insights from comparative transcriptome analysis of NAD-ME, NADP-ME, and PEP-CK C4 speciesIdentification of C4 photosynthesis metabolism and regulatory-associated genes in Eleocharis vivipara by SSH.The C(4) plant lineages of planet Earth.C4 cycles: past, present, and future research on C4 photosynthesis.PhotorespirationIndividual maize chromosomes in the C(3) plant oat can increase bundle sheath cell size and vein density.The development of C₄rice: current progress and future challenges.Characterizing regulatory and functional differentiation between maize mesophyll and bundle sheath cells by transcriptomic analysis.Leaf rolling allows quantification of mRNA abundance in mesophyll cells of sorghum.Systematic comparison of C3 and C4 plants based on metabolic network analysis.Strategies for engineering a two-celled C(4) photosynthetic pathway into rice.Are changes in sulfate assimilation pathway needed for evolution of C4 photosynthesis?Endoreduplication is not involved in bundle-sheath formation in the C4 species Cleome gynandra.Characterization of Rubisco activase genes in maize: an α-isoform gene functions alongside a β-isoform gene.Deep evolutionary comparison of gene expression identifies parallel recruitment of trans-factors in two independent origins of C4 photosynthesis.How do single cell C4 species form dimorphic chloroplasts?Developmental genetic mechanisms of C4 syndrome based on transcriptome analysis of C3 cotyledons and C4 assimilating shoots in Haloxylon ammodendron.Validating Internal Control Genes for the Accurate Normalization of qPCR Expression Analysis of the Novel Model Plant Setaria viridis.RNA-Seq based phylogeny recapitulates previous phylogeny of the genus Flaveria (Asteraceae) with some modifications.Identification of Photosynthesis-Associated C4 Candidate Genes through Comparative Leaf Gradient Transcriptome in Multiple Lineages of C3 and C4 Species.Production and Characterization of Synthetic Carboxysome Shells with Incorporated Luminal Proteins.Carbon isotope discrimination as a diagnostic tool for C4 photosynthesis in C3-C4 intermediate species.Evolution in agriculture: the application of evolutionary approaches to the management of biotic interactions in agro-ecosystems.Grand challenges in plant physiology: the underpinning of translational researchThe novel quantitative trait locus GL3.1 controls rice grain size and yield by regulating Cyclin-T1;3C3-C4 intermediacy in grasses: organelle enrichment and distribution, glycine decarboxylase expression, and the rise of C2 photosynthesis.
P2860
Q21128784-BD8E199B-5D40-45FF-947E-812D675A6B23Q24598955-80381376-166E-467F-8778-32DD75D2927FQ27003923-FDC5FA5E-AFD8-4681-85BC-6968999E2C65Q27024591-E1D69221-6318-418D-B404-8B70A3A03D96Q28075951-5DB65F4D-A345-47A0-90F1-3A69E880E01AQ28076100-3758E893-1E1A-488C-8EDE-3672B5256600Q28550773-8433BA24-BC8B-4134-B670-8AFEA79000DEQ28660254-AD5C086A-DAAF-4C9C-9ECA-B62A21EDD3EEQ28740606-484A24C9-6FF1-4134-8574-B5F4CFF789FDQ28818597-927BEB14-830D-4759-B50C-070940798D5FQ30396721-0FD12C20-0482-4373-B37E-0D6AACCE6A14Q33355813-A711A46B-2E43-4B4F-ABAE-DAB0F6628129Q33362399-E84566D6-BEBC-48DD-9C6B-FBDDB0A9FF18Q33577853-83B8B8BB-68BB-46B7-A797-A825D72F0E61Q33860129-98027286-73A9-4F9C-9BA5-2D0F5CE639B5Q33955594-DB7218FD-4C6C-45CE-8DCB-6837921158E2Q34171506-7F03469A-5239-41AF-BCF3-B7389F1378ECQ34236863-1C4D6DD5-B0BB-4166-A701-9DFF73648BD8Q34251815-1C8B46C9-3EE5-4061-AC37-3D6BC5617310Q34279517-956EE2B0-0F23-4361-B283-DF9426325AD1Q34284917-C8502410-0A98-450E-83AB-0ADE901941FBQ34350648-55A9B6E5-C31F-4B21-A703-A28570DF7906Q34450129-155BD7D5-1B4E-4896-BC11-A9BC051D5C76Q34529491-46048CF1-92C6-4211-979C-D0C9F3E3D20BQ34627094-E6387B31-63A1-4D61-AD83-ABFA0FA70781Q34933327-AC343E4D-0E2A-47F8-BF0E-8FE26B7DE59FQ35039541-33FF6725-5204-4065-8C19-9EF6FBB88ADCQ35089571-172342FA-8C3C-4459-989E-5DC75C97BB9FQ35182201-E638FC20-45B8-41BD-B25F-D52AEE710EE8Q35212519-581CFB51-C696-4210-953E-22DE84BF5641Q35553720-999EE243-3F99-4AF5-AC0E-E56B460A3F5EQ35738779-65CB958B-3BC0-4C6F-A9D3-C1175C958475Q35755293-CF549D8A-DF58-4EF5-95BE-1C579904D52DQ35805965-3BA9D763-0500-467F-AFD2-4394D3904D8BQ35899582-66146FF9-47FE-4518-A03F-BA1BEB6EBC1BQ35919245-631985E7-C5AA-48DF-92BA-A73B1B7F2913Q35961287-62AB183A-B5DA-4868-8C85-B05CA728A783Q35970550-D4894DF3-F9B6-46EE-9C99-1FE891043A85Q36449154-F42C7E33-DD6D-49A7-9352-87F4B750F2C6Q36903736-379B55DD-35DB-402C-91A6-5AE2ED145145
P2860
Using C4 photosynthesis to increase the yield of rice-rationale and feasibility.
description
2008 nî lūn-bûn
@nan
2008 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2008 թվականի հունվարին հրատարակված գիտական հոդված
@hy
2008年の論文
@ja
2008年論文
@yue
2008年論文
@zh-hant
2008年論文
@zh-hk
2008年論文
@zh-mo
2008年論文
@zh-tw
2008年论文
@wuu
name
Using C4 photosynthesis to increase the yield of rice-rationale and feasibility.
@ast
Using C4 photosynthesis to increase the yield of rice-rationale and feasibility.
@en
Using C4 photosynthesis to increase the yield of rice-rationale and feasibility.
@nl
type
label
Using C4 photosynthesis to increase the yield of rice-rationale and feasibility.
@ast
Using C4 photosynthesis to increase the yield of rice-rationale and feasibility.
@en
Using C4 photosynthesis to increase the yield of rice-rationale and feasibility.
@nl
prefLabel
Using C4 photosynthesis to increase the yield of rice-rationale and feasibility.
@ast
Using C4 photosynthesis to increase the yield of rice-rationale and feasibility.
@en
Using C4 photosynthesis to increase the yield of rice-rationale and feasibility.
@nl
P2093
P1476
Using C4 photosynthesis to increase the yield of rice-rationale and feasibility.
@en
P2093
Jane A Langdale
John E Sheehy
Julian M Hibberd
P304
P356
10.1016/J.PBI.2007.11.002
P577
2008-01-18T00:00:00Z