Control of root system architecture by DEEPER ROOTING 1 increases rice yield under drought conditions.
about
Growing Out of Stress: The Role of Cell- and Organ-Scale Growth Control in Plant Water-Stress ResponsesPlant adaptation to drought stressThe Nipponbare genome and the next-generation of rice genomics research in JapanEngineering food crops to grow in harsh environmentsApplication of genomics-assisted breeding for generation of climate resilient crops: progress and prospectsGenetic improvement for root growth angle to enhance crop productionGLO-Roots: an imaging platform enabling multidimensional characterization of soil-grown root systemsPlant Water Uptake in Drying SoilsRoots Withstanding their Environment: Exploiting Root System Architecture Responses to Abiotic Stress to Improve Crop ToleranceRoot System Architecture and Abiotic Stress Tolerance: Current Knowledge in Root and Tuber CropsDe novo Transcriptome Assembly of Common Wild Rice (Oryza rufipogon Griff.) and Discovery of Drought-Response Genes in Root Tissue Based on Transcriptomic DataRecent advances in the dissection of drought-stress regulatory networks and strategies for development of drought-tolerant transgenic rice plants.The transcriptional regulatory network in the drought response and its crosstalk in abiotic stress responses including drought, cold, and heat.Root length densities of UK wheat and oilseed rape crops with implications for water capture and yieldA late embryogenesis abundant protein HVA1 regulated by an inducible promoter enhances root growth and abiotic stress tolerance in rice without yield penalty.Genes controlling root development in riceAction of multiple intra-QTL genes concerted around a co-localized transcription factor underpins a large effect QTL.Abscisic acid regulates root growth under osmotic stress conditions via an interacting hormonal network with cytokinin, ethylene and auxin.CLE peptide signaling and nitrogen interactions in plant root development.Overexpression of the OsERF71 Transcription Factor Alters Rice Root Structure and Drought Resistance.OsPhyB-Mediating Novel Regulatory Pathway for Drought Tolerance in Rice Root Identified by a Global RNA-Seq Transcriptome Analysis of Rice Genes in Response to Water Deficiencies.Enhancing crop resilience to combined abiotic and biotic stress through the dissection of physiological and molecular crosstalk.The rice OsNAC6 transcription factor orchestrates multiple molecular mechanisms involving root structural adaptions and nicotianamine biosynthesis for drought tolerance.Harvesting the promising fruits of genomics: applying genome sequencing technologies to crop breedingMorphological Plant Modeling: Unleashing Geometric and Topological Potential within the Plant SciencesExpression of the Aeluropus littoralis AlSAP Gene Enhances Rice Yield under Field Drought at the Reproductive Stage.Genome-Wide Association Study Reveals Natural Variations Contributing to Drought Resistance in Crops.The function of OsbHLH068 is partially redundant with its homolog, AtbHLH112, in the regulation of the salt stress response but has opposite functions to control flowering in Arabidopsis.Coordinated regulation of photosynthesis in rice increases yield and tolerance to environmental stress.QTL analysis of root morphology, flowering time, and yield reveals trade-offs in response to drought in Brassica napus.Whole genome de novo assemblies of three divergent strains of rice, Oryza sativa, document novel gene space of aus and indica.Genome-wide association mapping of root traits in a japonica rice panel.Metabolomic response of Calotropis procera growing in the desert to changes in water availabilityA QTL for root growth angle on rice chromosome 7 is involved in the genetic pathway of DEEPER ROOTING 1.QTLs underlying natural variation of root growth angle among rice cultivars with the same functional allele of DEEPER ROOTING 1Wild barley introgression lines revealed novel QTL alleles for root and related shoot traits in the cultivated barley (Hordeum vulgare L.).Quantitative trait locus mapping of deep rooting by linkage and association analysis in rice.Beneficial Microbes Affect Endogenous Mechanisms Controlling Root Development.Genome-wide association mapping for root traits in a panel of rice accessions from VietnamMapping Quantitative Trait Loci Associated with Toot Traits Using Sequencing-Based Genotyping Chromosome Segment Substitution Lines Derived from 9311 and Nipponbare in Rice (Oryza sativa L.).
P2860
Q26738481-1BAD8A76-2F25-413B-B128-DD69A1BE9813Q26738600-1B96B087-1988-4769-A458-272641E81682Q26742016-4ED8BB71-D096-483D-AAFF-59A30E80B2EBQ26784195-6DC17627-34C2-4E3A-9075-C857D00A8287Q26795958-3D3A5462-01E8-4F7F-8F69-8B3C63E7BDBFQ26849328-AB38DC39-493D-42A5-BA4E-E4757C8946AAQ27708278-0EE32706-E920-4BAF-BB8A-1D1CE09E0666Q27708662-B79B9427-5FD0-48CE-8B3D-55E0177E4913Q28070109-4598AFB7-119B-4FC6-930D-3647ABA00A63Q28074519-9BB3FF16-1E8F-4DF2-A8D9-3702330C8727Q30000078-DAF5DF68-FAAC-4E15-A68D-22E8E2E3F164Q30389466-6295DC88-B86A-4483-8744-CAAF14C8B951Q30391565-D01B13DE-6582-45B7-A924-B2F6A2B3D466Q30906648-32E01AC9-4080-4E3F-870E-18C6379CD21AQ33359056-CFDA4C7B-DEFE-4724-B46E-095EE40CE20BQ33361221-BAE70447-6754-4EBB-8E63-AAB016FEDC15Q33361804-17051178-ADB8-4A86-B172-0E7D2E7F1B9AQ33362607-13C7FF71-0BA1-459F-BEF2-578D984DABB8Q33362812-4C2C49B1-5878-4F0E-8A17-697AB532F333Q33363458-2B0ED5AF-72BA-4CEA-B658-0A78D38581EAQ33603493-8E6DD8C6-9D43-4BDD-997E-1B0A1E2330F4Q33657895-C261B4AC-DD8E-433A-A0CA-DDD263DCA76EQ33658523-69EC85FC-7602-478E-93A7-2D1E93EB4759Q33733918-07908294-2B50-4C1A-B33B-BE4EABC62E22Q33780835-9165065A-7974-42CF-B0F0-CB782B34E4CEQ33785763-C2FAE704-BF4B-4B54-BBD9-FC487BA0D1FFQ33854702-E99407BD-AEF7-4F56-AA34-71A81D139822Q33890599-53529C05-DCE9-480F-BD06-DE759DDDF0F3Q34453812-FFBC8816-D72F-4CCB-8BD6-80785EEC829BQ34692637-EA483AAE-1903-44C2-8F06-080922D7AB6AQ34720742-03CF7A6D-BA6C-44E7-B317-98DAE8CB4CF2Q35040759-42AF8595-BD66-488C-BAB3-346C64A204C9Q35092669-7A30B421-8A46-4843-876A-F3B37FBCFAC8Q35261442-9A171ADC-04E8-436D-913F-39BB486DF5CFQ35267047-7FE51FD2-2877-46F9-8427-82852320389DQ35305830-C57712DB-8F38-4914-ACA8-FC542F931202Q35867068-1AC45B34-7444-4997-AB09-987A9A698FD1Q35923322-88B26187-2CA2-4E44-9F9F-91D368ACDC0CQ35953094-A34C5245-C82E-4EAA-9447-CABEEF033D48Q35969082-5E6C9AF5-5D10-43C0-B741-F5C9168F4E1A
P2860
Control of root system architecture by DEEPER ROOTING 1 increases rice yield under drought conditions.
description
2013 nî lūn-bûn
@nan
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
2013年论文
@zh
2013年论文
@zh-cn
name
Control of root system archite ...... ield under drought conditions.
@en
Control of root system archite ...... ield under drought conditions.
@nl
type
label
Control of root system archite ...... ield under drought conditions.
@en
Control of root system archite ...... ield under drought conditions.
@nl
prefLabel
Control of root system archite ...... ield under drought conditions.
@en
Control of root system archite ...... ield under drought conditions.
@nl
P2093
P356
P1433
P1476
Control of root system archite ...... ield under drought conditions.
@en
P2093
Haruhiko Inoue
Hinako Takehisa
Jagadish Rane
Jianzhong Wu
Kazuhiko Sugimoto
Kazuko Ono
Kazutoshi Okuno
Manabu Ishitani
Masahiro Yano
P2888
P304
P356
10.1038/NG.2725
P407
P577
2013-08-04T00:00:00Z