Integration of root phenes for soil resource acquisition.
about
Root adaptations to soils with low fertility and aluminium toxicityRoot anatomical phenes associated with water acquisition from drying soil: targets for crop improvementRoot System Architecture and Abiotic Stress Tolerance: Current Knowledge in Root and Tuber CropsRoot cortical aerenchyma enhances nitrogen acquisition from low-nitrogen soils in maizeAn ontology approach to comparative phenomics in plantsTranscript profiles in cortical cells of maize primary root during ethylene-induced lysigenous aerenchyma formation under aerobic conditions.Evolution of US maize (Zea mays L.) root architectural and anatomical phenes over the past 100 years corresponds to increased tolerance of nitrogen stress.Root foraging elicits niche complementarity-dependent yield advantage in the ancient 'three sisters' (maize/bean/squash) polycultureRoot anatomical phenes predict root penetration ability and biomechanical properties in maize (Zea Mays).Multiple interval QTL mapping and searching for PSTOL1 homologs associated with root morphology, biomass accumulation and phosphorus content in maize seedlings under low-P.Intensive field phenotyping of maize (Zea mays L.) root crowns identifies phenes and phene integration associated with plant growth and nitrogen acquisitionComparative Morphophysiological Analyses and Molecular Profiling Reveal Pi-Efficient Strategies of a Traditional Rice Genotype.Root Traits and Phenotyping Strategies for Plant ImprovementThe roots of future rice harvests.Reduced crown root number improves water acquisition under water deficit stress in maize (Zea mays L.).Genetic Diversity under Soil Compaction in Wheat: Root Number as a Promising Trait for Early Plant Vigor.Root phenes that reduce the metabolic costs of soil exploration: opportunities for 21st century agriculture.The holistic rhizosphere: integrating zones, processes, and semantics in the soil influenced by roots.How can we harness quantitative genetic variation in crop root systems for agricultural improvement?Rice Root Architectural Plasticity Traits and Genetic Regions for Adaptability to Variable Cultivation and Stress Conditions.Screening for drought tolerance of maize hybrids by multi-scale analysis of root and shoot traits at the seedling stage.Reduced root cortical cell file number improves drought tolerance in maize.Large root cortical cell size improves drought tolerance in maize.Evaluation of high yielding soybean germplasm under water limitation.Root and rhizosphere processes-high time to dig deeper.Spatiotemporal variation of nitrate uptake kinetics within the maize (Zea mays L.) root system is associated with greater nitrate uptake and interactions with architectural phenes.Reduced Lateral Root Branching Density Improves Drought Tolerance in Maize.New insights into trophic aerenchyma formation strategy in maize (Zea mays L.) organs during sulfate deprivation.Reduction in Root Secondary Growth as a Strategy for Phosphorus Acquisition.Low crown root number enhances nitrogen acquisition from low-nitrogen soils in maize.Phene synergism between root hair length and basal root growth angle for phosphorus acquisition.Root Cortical Senescence Improves Growth under Suboptimal Availability of N, P, and K.Image-based high-throughput field phenotyping of crop roots.QTL mapping and phenotypic variation of root anatomical traits in maize (Zea mays L.).
P2860
Q26743871-295C6192-ABBE-4949-B0A9-267C038A4354Q26830054-D7B87B4F-CA11-41BA-8F9F-18ED282463E4Q28074519-F0E14EDD-80C1-43DD-8C25-0751070900D1Q28654218-99DBEABA-CBE1-4F4D-B3C6-0CAB87569874Q35176945-ADBA3112-F3B0-45C6-823B-F1CBFCB65DC4Q35529454-2C2DFA89-43C3-4553-A3C9-2B2C20CC4E62Q35531584-AEC0C0A4-4BF1-4214-9B1D-BF73F08A3D29Q35558855-F5971D47-78E0-483D-A2C3-CB7054C23BC1Q35666797-4DE7E5DE-5AA6-4ACB-A57B-0CC9643D7929Q35684377-EC89F0E6-FE8C-47CF-85B9-277A3CF832FAQ36098558-F6774FF5-F855-4888-9063-9D920D58039FQ36427117-2BEEE51C-96C6-45D9-9C91-ABDA84E3D82DQ36833701-D2C6C637-1473-4E59-B9BB-7A55DD0FE2BCQ36944445-B5DD6584-195C-4790-B464-BD287D8BA318Q37152426-EDD586A9-EE6B-480B-A7EC-3B0B21C717C8Q37723451-8BF28DB2-CDCC-4FA4-810A-01198AA8D2E0Q38254263-C4E50F53-AA09-4220-98E6-BC3820447A8EQ38394761-6AEBFA56-ECA1-418B-8D6D-30160717052FQ38748917-F60616F4-4721-483E-9C58-AD35DFB4D6B8Q38848736-02541920-BC8A-4390-96F4-2F2FD956C601Q38884426-01363EA4-C4FC-4AA7-9423-E22D55DE5DB4Q38944478-4A2C75EC-4274-498A-AA4B-C51ED3C226C6Q38944483-9D6561C5-3F7A-428B-9925-3CF4EE69AE81Q39369221-9632D0D6-AF0B-4FD1-BC6B-34F8BC93ED47Q39394277-E9AAB5FB-5E0C-463D-9556-472F28AF4D95Q39617171-E4246E8A-D705-4442-B941-4B7B107A754AQ39624906-881A7351-8A75-45E1-A7E6-DC33107048D3Q41781511-86833CCD-C1B1-4907-82A9-64AC610C9D8DQ46265470-8FDDFFC0-811F-490B-92BA-831256103B72Q46597124-07CE2D61-A560-4A5C-BCC2-EB025E966309Q46770074-6C410019-336D-4879-A454-3497BB7A9430Q47846873-F4495EAB-574B-4EBE-B9D9-1D97029B19CEQ48272550-891F4419-71FD-456C-8430-6A6D23FC8737Q48536425-C5C2E5E2-CDC2-482B-9FCA-74E2E0A4E0DF
P2860
Integration of root phenes for soil resource acquisition.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 12 September 2013
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Integration of root phenes for soil resource acquisition.
@en
Integration of root phenes for soil resource acquisition.
@nl
type
label
Integration of root phenes for soil resource acquisition.
@en
Integration of root phenes for soil resource acquisition.
@nl
prefLabel
Integration of root phenes for soil resource acquisition.
@en
Integration of root phenes for soil resource acquisition.
@nl
P2860
P356
P1476
Integration of root phenes for soil resource acquisition.
@en
P2093
Eric A Nord
Jonathan P Lynch
P2860
P356
10.3389/FPLS.2013.00355
P50
P577
2013-09-12T00:00:00Z